/* -*- mode: C -*-  */
/*
   IGraph library.
   Copyright (C) 2003-2012  Gabor Csardi <csardi.gabor@gmail.com>
   334 Harvard street, Cambridge, MA 02139 USA

   This program is free software; you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation; either version 2 of the License, or
   (at your option) any later version.

   This program is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program; if not, write to the Free Software
   Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
   02110-1301 USA

*/

#include "igraph_memory.h"
#include "igraph_error.h"
#include "igraph_random.h"
#include "igraph_qsort.h"

#include "math/safe_intop.h"

#include <string.h>         /* memcpy & co. */
#include <stdlib.h>
#include <stdarg.h>     /* va_start & co */
#include <math.h>

/**
 * \ingroup vector
 * \section about_igraph_vector_t_objects About \type igraph_vector_t objects
 *
 * <para>The \type igraph_vector_t data type is a simple and efficient
 * interface to arrays containing numbers. It is something similar to (but much
 * simpler than) the \type vector template in the C++ standard library.</para>
 *
 * <para>There are multiple variants of \type igraph_vector_t; the basic variant
 * stores doubles, but there is also \type igraph_vector_int_t for integers (of
 * type \type igraph_integer_t), \c igraph_vector_bool_t for booleans (of type
 * \type igraph_bool_t) and so on. Vectors are used extensively in \a igraph; all
 * functions that expect or return a list of numbers use \type igraph_vector_t or
 * \type igraph_vector_int_t to achieve this. Integer vectors are typically used
 * when the vector is supposed to hold vertex or edge identifiers, while
 * \type igraph_vector_t is used when the vector is expected to hold fractional
 * numbers or infinities.</para>
 *
 * <para>The \type igraph_vector_t type and its variants usually use O(n) space
 * to store n elements. Sometimes they use more, this is because vectors can
 * shrink, but even if they shrink, the current implementation does not free a
 * single bit of memory.</para>
 *
 * <para>The elements in an \type igraph_vector_t object and its variants are
 * indexed from zero, we follow the usual C convention here.</para>
 *
 * <para>The elements of a vector always occupy a single block of
 * memory, the starting address of this memory block can be queried
 * with the \ref VECTOR macro. This way, vector objects can be used
 * with standard mathematical libraries, like the GNU Scientific
 * Library.</para>
 *
 * <para>Almost all of the functions described below for \type igraph_vector_t
 * also exist for all the other vector type variants. These variants are not
 * documented separately; you can simply replace \c vector with \c vector_int,
 * \c vector_bool or something similar if you need a function for another
 * variant. For instance, to initialize a vector of type \type igraph_vector_int_t,
 * you need to use \ref igraph_vector_int_init() and not \ref igraph_vector_init().</para>
 */

/**
 * \ingroup vector
 * \section igraph_vector_constructors_and_destructors Constructors and
 * destructors
 *
 * <para>\type igraph_vector_t objects have to be initialized before using
 * them, this is analogous to calling a constructor on them. There are a
 * number of \type igraph_vector_t constructors, for your
 * convenience. \ref igraph_vector_init() is the basic constructor, it
 * creates a vector of the given length, filled with zeros.
 * \ref igraph_vector_init_copy() creates a new identical copy
 * of an already existing and initialized vector. \ref
 * igraph_vector_init_array() creates a vector by copying a regular C array.
 * \ref igraph_vector_init_range() creates a vector containing a regular
 * sequence with increment one.</para>
 *
 * <para>\ref igraph_vector_view() is a special constructor, it allows you to
 * handle a regular C array as a \type vector without copying
 * its elements.
 * </para>
 *
 * <para>If a \type igraph_vector_t object is not needed any more, it
 * should be destroyed to free its allocated memory by calling the
 * \type igraph_vector_t destructor, \ref igraph_vector_destroy().</para>
 *
 * <para> Note that vectors created by \ref igraph_vector_view() are special,
 * you must not call \ref igraph_vector_destroy() on these.</para>
 */

/**
 * \ingroup vector
 * \function igraph_vector_init
 * \brief Initializes a vector object (constructor).
 *
 * </para><para>
 * Every vector needs to be initialized before it can be used, and
 * there are a number of initialization functions or otherwise called
 * constructors. This function constructs a vector of the given size and
 * initializes each entry to 0. Note that \ref igraph_vector_null() can be
 * used to set each element of a vector to zero. However, if you want a
 * vector of zeros, it is much faster to use this function than to create a
 * vector and then invoke \ref igraph_vector_null().
 *
 * </para><para>
 * Every vector object initialized by this function should be
 * destroyed (ie. the memory allocated for it should be freed) when it
 * is not needed anymore, the \ref igraph_vector_destroy() function is
 * responsible for this.
 * \param v Pointer to a not yet initialized vector object.
 * \param size The size of the vector.
 * \return error code:
 *       \c IGRAPH_ENOMEM if there is not enough memory.
 *
 * Time complexity: operating system dependent, the amount of
 * \quote time \endquote required to allocate
 * O(n) elements,
 * n is the number of elements.
 */

igraph_error_t FUNCTION(igraph_vector, init)(TYPE(igraph_vector) *v, igraph_integer_t size) {
    igraph_integer_t alloc_size;
    IGRAPH_ASSERT(size >= 0);
    alloc_size = size > 0 ? size : 1;

    /* When this function fails, it should leave stor_begin set to NULL,
     * so that vector_destroy() is still safe to call on the vector.
     * This simplifies freeing partially initialized data structures,
     * such as adjacency lists, when an error occurs mid-initialization. */
    v->stor_begin = IGRAPH_CALLOC(alloc_size, BASE);
    if (v->stor_begin == NULL) {
        IGRAPH_ERROR("Cannot initialize vector.", IGRAPH_ENOMEM); /* LCOV_EXCL_LINE */
    }
    v->stor_end = v->stor_begin + alloc_size;
    v->end = v->stor_begin + size;

    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_view
 * \brief Handle a regular C array as a \type igraph_vector_t.
 *
 * </para><para>
 * This is a special \type igraph_vector_t constructor. It allows to
 * handle a regular C array as a \type igraph_vector_t temporarily.
 * Be sure that you \em don't ever call the destructor (\ref
 * igraph_vector_destroy()) on objects created by this constructor.
 * \param v Pointer to an uninitialized \type igraph_vector_t object.
 * \param data Pointer, the C array. It may not be \c NULL, except
 *     when \p length is zero.
 * \param length The length of the C array.
 * \return Pointer to the vector object, the same as the
 *     \p v parameter, for convenience.
 *
 * Time complexity: O(1)
 */

const TYPE(igraph_vector)* FUNCTION(igraph_vector, view)(const TYPE(igraph_vector) *v,
        const BASE *data, igraph_integer_t length) {
    static const BASE dummy = ZERO;
    TYPE(igraph_vector) *v2 = (TYPE(igraph_vector)*)v;

    /* When the length is zero, we allow 'data' to be NULL.
     * An igraph_vector_t may never contain a NULL pointer,
     * thus we use a pointer to a dummy variable in this case. */
    if (length == 0) {
        data = &dummy;
    } else {
        IGRAPH_ASSERT(data != NULL);
    }

    v2->stor_begin = (BASE*)data;
    v2->stor_end = (BASE*)data + length;
    v2->end = v2->stor_end;
    return v;
}

#ifndef BASE_COMPLEX

/**
 * \ingroup vector
 * \function igraph_vector_init_real
 * \brief Create an \type igraph_vector_t from the parameters.
 *
 * </para><para>
 * Because of how C and the C library handles variable length argument
 * lists, it is required that you supply real constants to this
 * function. This means that
 * \verbatim igraph_vector_t v;
 * igraph_vector_init_real(&amp;v, 5, 1,2,3,4,5); \endverbatim
 * is an error at runtime and the results are undefined. This is
 * the proper way:
 * \verbatim igraph_vector_t v;
 * igraph_vector_init_real(&amp;v, 5, 1.0,2.0,3.0,4.0,5.0); \endverbatim
 * \param v Pointer to an uninitialized \type igraph_vector_t object.
 * \param no Positive integer, the number of \type igraph_real_t
 *    parameters to follow.
 * \param ... The elements of the vector.
 * \return Error code, this can be \c IGRAPH_ENOMEM
 *     if there isn't enough memory to allocate the vector.
 *
 * \sa \ref igraph_vector_init_real_end(), \ref igraph_vector_init_int() for similar
 * functions.
 *
 * Time complexity: depends on the time required to allocate memory,
 * but at least O(n), the number of
 * elements in the vector.
 */

igraph_error_t FUNCTION(igraph_vector, init_real)(TYPE(igraph_vector) *v, int no, ...) {
    int i = 0;
    va_list ap;
    IGRAPH_CHECK(FUNCTION(igraph_vector, init)(v, no));

    va_start(ap, no);
    for (i = 0; i < no; i++) {
        VECTOR(*v)[i] = (BASE) va_arg(ap, double);
    }
    va_end(ap);

    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_init_real_end
 * \brief Create an \type igraph_vector_t from the parameters.
 *
 * </para><para>
 * This constructor is similar to \ref igraph_vector_init_real(), the only
 * difference is that instead of giving the number of elements in the
 * vector, a special marker element follows the last real vector
 * element.
 * \param v Pointer to an uninitialized \type igraph_vector_t object.
 * \param endmark This element will signal the end of the vector. It
 *    will \em not be part of the vector.
 * \param ... The elements of the vector.
 * \return Error code, \c IGRAPH_ENOMEM if there
 *    isn't enough memory.
 *
 * \sa \ref igraph_vector_init_real() and \ref igraph_vector_init_int_end() for
 * similar functions.
 *
 * Time complexity: at least O(n) for
 * n elements plus the time
 * complexity of the memory allocation.
 */

igraph_error_t FUNCTION(igraph_vector, init_real_end)(TYPE(igraph_vector) *v,
        double endmark, ...) {
    int i = 0, n = 0;
    va_list ap;

    va_start(ap, endmark);
    while (1) {
        BASE num = (BASE) va_arg(ap, double);
        if (num == endmark) {
            break;
        }
        n++;
    }
    va_end(ap);

    IGRAPH_CHECK(FUNCTION(igraph_vector, init)(v, n));
    IGRAPH_FINALLY(FUNCTION(igraph_vector, destroy), v);

    va_start(ap, endmark);
    for (i = 0; i < n; i++) {
        VECTOR(*v)[i] = (BASE) va_arg(ap, double);
    }
    va_end(ap);

    IGRAPH_FINALLY_CLEAN(1);
    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_init_int
 * \brief Create an \type igraph_vector_t containing the parameters.
 *
 * </para><para>
 * This function is similar to \ref igraph_vector_init_real(), but it expects
 * \type int parameters. It is important that all parameters
 * should be of this type, otherwise the result of the function call
 * is undefined.
 * \param v Pointer to an uninitialized \type igraph_vector_t object.
 * \param no The number of \type int parameters to follow.
 * \param ... The elements of the vector.
 * \return Error code, \c IGRAPH_ENOMEM if there is
 *    not enough memory.
 * \sa \ref igraph_vector_init_real() and \ref igraph_vector_init_int_end(), these are
 *    similar functions.
 *
 * Time complexity: at least O(n) for
 * n elements plus the time
 * complexity of the memory allocation.
 */

igraph_error_t FUNCTION(igraph_vector, init_int)(TYPE(igraph_vector) *v, int no, ...) {
    int i = 0;
    va_list ap;
    IGRAPH_CHECK(FUNCTION(igraph_vector, init)(v, no));

    va_start(ap, no);
    for (i = 0; i < no; i++) {
        VECTOR(*v)[i] = (BASE) va_arg(ap, int);
    }
    va_end(ap);

    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_init_int_end
 * \brief Create an \type igraph_vector_t from the parameters.
 *
 * </para><para>
 * This constructor is similar to \ref igraph_vector_init_int(), the only
 * difference is that instead of giving the number of elements in the
 * vector, a special marker element follows the last real vector
 * element.
 * \param v Pointer to an uninitialized \type igraph_vector_t object.
 * \param endmark This element will signal the end of the vector. It
 *    will \em not be part of the vector.
 * \param ... The elements of the vector.
 * \return Error code, \c IGRAPH_ENOMEM if there
 *    isn't enough memory.
 *
 * \sa \ref igraph_vector_init_int() and \ref igraph_vector_init_real_end() for
 * similar functions.
 *
 * Time complexity: at least O(n) for
 * n elements plus the time
 * complexity of the memory allocation.
 */

igraph_error_t FUNCTION(igraph_vector, init_int_end)(TYPE(igraph_vector) *v, int endmark, ...) {
    int i = 0, n = 0;
    va_list ap;

    va_start(ap, endmark);
    while (1) {
        int num = va_arg(ap, int);
        if (num == endmark) {
            break;
        }
        n++;
    }
    va_end(ap);

    IGRAPH_CHECK(FUNCTION(igraph_vector, init)(v, n));
    IGRAPH_FINALLY(FUNCTION(igraph_vector, destroy), v);

    va_start(ap, endmark);
    for (i = 0; i < n; i++) {
        VECTOR(*v)[i] = (BASE) va_arg(ap, int);
    }
    va_end(ap);

    IGRAPH_FINALLY_CLEAN(1);
    return IGRAPH_SUCCESS;
}

#endif /* ifndef BASE_COMPLEX */

/**
 * \ingroup vector
 * \function igraph_vector_destroy
 * \brief Destroys a vector object.
 *
 * </para><para>
 * All vectors initialized by \ref igraph_vector_init() should be properly
 * destroyed by this function. A destroyed vector needs to be
 * reinitialized by \ref igraph_vector_init(), \ref igraph_vector_init_array() or
 * another constructor.
 * \param v Pointer to the (previously initialized) vector object to
 *        destroy.
 *
 * Time complexity: operating system dependent.
 */

void FUNCTION(igraph_vector, destroy)(TYPE(igraph_vector) *v) {
    IGRAPH_ASSERT(v != NULL);
    /* vector_init() will leave stor_begin set to NULL when it fails.
     * We handle these cases gracefully. */
    if (v->stor_begin != NULL) {
        IGRAPH_FREE(v->stor_begin);
        v->stor_begin = NULL;
    }
}

/**
 * \ingroup vector
 * \function igraph_vector_capacity
 * \brief Returns the allocated capacity of the vector.
 *
 * Note that this might be different from the size of the vector (as
 * queried by \ref igraph_vector_size()), and specifies how many elements
 * the vector can hold, without reallocation.
 *
 * \param v Pointer to the (previously initialized) vector object
 *          to query.
 * \return The allocated capacity.
 *
 * \sa \ref igraph_vector_size().
 *
 * Time complexity: O(1).
 */

igraph_integer_t FUNCTION(igraph_vector, capacity)(const TYPE(igraph_vector) *v) {
    return v->stor_end - v->stor_begin;
}

/**
 * \ingroup vector
 * \function igraph_vector_reserve
 * \brief Reserves memory for a vector.
 *
 * </para><para>
 * \a igraph vectors are flexible, they can grow and
 * shrink. Growing
 * however occasionally needs the data in the vector to be copied.
 * In order to avoid this, you can call this function to reserve space for
 * future growth of the vector.
 *
 * </para><para>
 * Note that this function does \em not change the size of the
 * vector. Let us see a small example to clarify things: if you
 * reserve space for 100 elements and the size of your
 * vector was (and still is) 60, then you can surely add additional 40
 * elements to your vector before it will be copied.
 * \param v The vector object.
 * \param capacity The new \em allocated size of the vector.
 * \return Error code:
 *         \c IGRAPH_ENOMEM if there is not enough memory.
 *
 * Time complexity: operating system dependent, should be around
 * O(n), n
 * is the new allocated size of the vector.
 */

igraph_error_t FUNCTION(igraph_vector, reserve)(TYPE(igraph_vector) *v, igraph_integer_t capacity) {
    igraph_integer_t current_capacity;
    BASE *tmp;

    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    IGRAPH_ASSERT(capacity >= 0);

    current_capacity = FUNCTION(igraph_vector, capacity)(v);

    if (capacity <= current_capacity) {
        return IGRAPH_SUCCESS;
    }

    tmp = IGRAPH_REALLOC(v->stor_begin, capacity, BASE);
    IGRAPH_CHECK_OOM(tmp, "Cannot reserve space for vector.");

    v->end = tmp + (v->end - v->stor_begin);
    v->stor_begin = tmp;
    v->stor_end = v->stor_begin + capacity;

    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_empty
 * \brief Decides whether the size of the vector is zero.
 *
 * \param v The vector object.
 * \return True if the size of the vector is zero and false otherwise.
 *
 * Time complexity: O(1).
 */

igraph_bool_t FUNCTION(igraph_vector, empty)(const TYPE(igraph_vector) *v) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    return v->stor_begin == v->end;
}

/**
 * \ingroup vector
 * \function igraph_vector_size
 * \brief The size of the vector.
 *
 * Returns the number of elements stored in the vector.
 *
 * \param v The vector object
 * \return The size of the vector.
 *
 * Time complexity: O(1).
 */

igraph_integer_t FUNCTION(igraph_vector, size)(const TYPE(igraph_vector) *v) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    return v->end - v->stor_begin;
}

/**
 * \ingroup vector
 * \function igraph_vector_clear
 * \brief Removes all elements from a vector.
 *
 * </para><para>
 * This function simply sets the size of the vector to zero, it does
 * not free any allocated memory. For that you have to call
 * \ref igraph_vector_destroy().
 * \param v The vector object.
 *
 * Time complexity: O(1).
 */

void FUNCTION(igraph_vector, clear)(TYPE(igraph_vector)* v) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    v->end = v->stor_begin;
}

/**
 * \ingroup vector
 * \function igraph_vector_push_back
 * \brief Appends one element to a vector.
 *
 * This function resizes the vector to be one element longer and
 * sets the very last element in the vector to \p e.
 *
 * \param v The vector object.
 * \param e The element to append to the vector.
 * \return Error code:
 *         \c IGRAPH_ENOMEM: not enough memory.
 *
 * Time complexity: operating system dependent. What is important is that
 * a sequence of n
 * subsequent calls to this function has time complexity
 * O(n), even if there
 * hadn't been any space reserved for the new elements by
 * \ref igraph_vector_reserve(). This is implemented by a trick similar to the C++
 * \type vector class: each time more memory is allocated for a
 * vector, the size of the additionally allocated memory is the same
 * as the vector's current length. (We assume here that the time
 * complexity of memory allocation is at most linear.)
 */

igraph_error_t FUNCTION(igraph_vector, push_back)(TYPE(igraph_vector) *v, BASE e) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);

    if (v->stor_end == v->end) {
        /* full, allocate more storage */
        igraph_integer_t old_size = FUNCTION(igraph_vector, size)(v);
        igraph_integer_t new_size = old_size < IGRAPH_INTEGER_MAX/2 ? old_size * 2 : IGRAPH_INTEGER_MAX;
        if (old_size == IGRAPH_INTEGER_MAX) {
            IGRAPH_ERROR("Cannot push to vector, already at maximum size.", IGRAPH_EOVERFLOW);
        }
        if (new_size == 0) {
            new_size = 1;
        }
        IGRAPH_CHECK(FUNCTION(igraph_vector, reserve)(v, new_size));
    }

    *(v->end) = e;
    v->end += 1;

    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_insert
 * \brief Inserts a single element into a vector.
 *
 * Note that this function does not do range checking. Insertion will shift the
 * elements from the position given to the end of the vector one position to the
 * right, and the new element will be inserted in the empty space created at
 * the given position. The size of the vector will increase by one.
 *
 * \param v The vector object.
 * \param pos The position where the new element is to be inserted.
 * \param value The new element to be inserted.
 */
igraph_error_t FUNCTION(igraph_vector, insert)(
        TYPE(igraph_vector) *v, igraph_integer_t pos, BASE value) {
    igraph_integer_t size = FUNCTION(igraph_vector, size)(v);
    IGRAPH_ASSERT(0 <= pos && pos <= size);
    if (size == IGRAPH_INTEGER_MAX) {
        IGRAPH_ERROR("Cannot insert to vector, already at maximum size.", IGRAPH_EOVERFLOW);
    }
    IGRAPH_CHECK(FUNCTION(igraph_vector, resize)(v, size + 1));
    if (pos < size) {
        memmove(v->stor_begin + pos + 1, v->stor_begin + pos,
                sizeof(BASE) * (size - pos));
    }
    v->stor_begin[pos] = value;
    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \section igraph_vector_accessing_elements Accessing elements
 *
 * <para>The simplest and most performant way to access an element of a vector is
 * to use the \ref VECTOR macro. This macro can be used both for querying and setting
 * \type igraph_vector_t elements. If you need a function, \ref
 * igraph_vector_get() queries and \ref igraph_vector_set() sets an element of a
 * vector. \ref igraph_vector_get_ptr() returns the address of an element.</para>
 *
 * <para>\ref igraph_vector_tail() returns the last element of a non-empty
 * vector. There is no <function>igraph_vector_head()</function> function
 * however, as it is easy to write <code>VECTOR(v)[0]</code>
 * instead.</para>
 */

/**
 * \ingroup vector
 * \function igraph_vector_get
 * \brief Access an element of a vector.
 *
 * Unless you need a function, consider using the \ref VECTOR
 * macro instead for better performance.
 *
 * \param v The \type igraph_vector_t object.
 * \param pos The position of the element, the index of the first
 *    element is zero.
 * \return The desired element.
 * \sa \ref igraph_vector_get_ptr() and the \ref VECTOR macro.
 *
 * Time complexity: O(1).
 */

BASE FUNCTION(igraph_vector, get)(const TYPE(igraph_vector) *v, igraph_integer_t pos) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    return * (v->stor_begin + pos);
}

/**
 * \ingroup vector
 * \function igraph_vector_get_ptr
 * \brief Get the address of an element of a vector.
 *
 * Unless you need a function, consider using the \ref VECTOR
 * macro instead for better performance.
 *
 * \param v The \type igraph_vector_t object.
 * \param pos The position of the element, the position of the first
 *   element is zero.
 * \return Pointer to the desired element.
 * \sa \ref igraph_vector_get() and the \ref VECTOR macro.
 *
 * Time complexity: O(1).
 */

BASE* FUNCTION(igraph_vector, get_ptr)(const TYPE(igraph_vector) *v, igraph_integer_t pos) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    return v->stor_begin + pos;
}

/**
 * \ingroup vector
 * \function igraph_vector_e
 * \brief Access an element of a vector (deprecated alias).
 *
 * \deprecated-by igraph_vector_get 0.10.0
 */

BASE FUNCTION(igraph_vector, e)(const TYPE(igraph_vector) *v, igraph_integer_t pos) {
    return FUNCTION(igraph_vector, get)(v, pos);
}

/**
 * \ingroup vector
 * \function igraph_vector_e_ptr
 * \brief Get the address of an element of a vector.
 *
 * \param v The \type igraph_vector_t object.
 * \param pos The position of the element, the position of the first
 *   element is zero.
 * \return Pointer to the desired element.
 * \sa \ref igraph_vector_get() and the \ref VECTOR macro.
 *
 * Time complexity: O(1).
 */

BASE* FUNCTION(igraph_vector, e_ptr)(const TYPE(igraph_vector) *v, igraph_integer_t pos) {
    return FUNCTION(igraph_vector, get_ptr)(v, pos);
}

/**
 * \ingroup vector
 * \function igraph_vector_set
 * \brief Assignment to an element of a vector.
 *
 * Unless you need a function, consider using the \ref VECTOR
 * macro instead for better performance.
 *
 * \param v The \type igraph_vector_t element.
 * \param pos Position of the element to set.
 * \param value New value of the element.
 * \sa \ref igraph_vector_get().
 */

void FUNCTION(igraph_vector, set)(TYPE(igraph_vector) *v, igraph_integer_t pos, BASE value) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    *(v->stor_begin + pos) = value;
}

/**
 * \ingroup vector
 * \function igraph_vector_null
 * \brief Sets each element in the vector to zero.
 *
 * </para><para>
 * Note that \ref igraph_vector_init() sets the elements to zero as well, so
 * it makes no sense to call this function on a just initialized
 * vector. Thus if you want to construct a vector of zeros, then you should
 * use \ref igraph_vector_init().
 *
 * \param v The vector object.
 *
 * Time complexity: O(n), the size of
 * the vector.
 */

void FUNCTION(igraph_vector, null)(TYPE(igraph_vector) *v) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    if (FUNCTION(igraph_vector, size)(v) > 0) {
        memset(v->stor_begin, 0, sizeof(BASE) * FUNCTION(igraph_vector, size)(v));
    }
}

/**
 * \function igraph_vector_fill
 * \brief Fill a vector with a constant element.
 *
 * Sets each element of the vector to the supplied constant.
 *
 * \param vector The vector to work on.
 * \param e The element to fill with.
 *
 * Time complexity: O(n), the size of the vector.
 */

void FUNCTION(igraph_vector, fill)(TYPE(igraph_vector) *v, BASE e) {
    BASE *ptr;
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    for (ptr = v->stor_begin; ptr < v->end; ptr++) {
        *ptr = e;
    }
}

#ifndef NOTORDERED

/**
 * \ingroup vector
 * \function igraph_vector_range
 * \brief Updates a vector to store a range.
 *
 * Sets the elements of the vector to contain the numbers \p start, \p start+1,
 * ..., \p end-1. Note that the range is closed from the left and open from the
 * right, according to C conventions. The vector will be resized to fit the range.
 *
 * \param v The vector to update.
 * \param start The lower limit in the range (inclusive).
 * \param end The upper limit in the range (exclusive).
 * \return Error code:
 *         \c IGRAPH_ENOMEM: out of memory.
 *
 * Time complexity: O(n), the number of elements in the vector.
 */

igraph_error_t FUNCTION(igraph_vector, range)(TYPE(igraph_vector) *v, BASE start, BASE end) {
    BASE *p;
    IGRAPH_CHECK(FUNCTION(igraph_vector, resize)(v, (end - start)));

    for (p = v->stor_begin; p < v->end; p++) {
        *p = start;
        start = start + ONE;
    }

    return IGRAPH_SUCCESS;
}

#endif

/**
 * \ingroup vector
 * \function igraph_vector_tail
 * \brief Returns the last element in a vector.
 *
 * It is an error to call this function on an empty vector, the result
 * is undefined.
 *
 * \param v The vector object.
 * \return The last element.
 *
 * Time complexity: O(1).
 */

BASE FUNCTION(igraph_vector, tail)(const TYPE(igraph_vector) *v) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    return *((v->end) - 1);
}

/**
 * \ingroup vector
 * \function igraph_vector_pop_back
 * \brief Removes and returns the last element of a vector.
 *
 * It is an error to call this function with an empty vector.
 *
 * \param v The vector object.
 * \return The removed last element.
 *
 * Time complexity: O(1).
 */

BASE FUNCTION(igraph_vector, pop_back)(TYPE(igraph_vector) *v) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    IGRAPH_ASSERT(v->end != NULL);
    IGRAPH_ASSERT(v->end != v->stor_begin);

    (v->end)--;

    return *(v->end);
}

#ifndef NOTORDERED

/**
 * \ingroup vector
 * \function igraph_vector_permute
 * \brief Permutes the elements of a vector in place according to an index vector.
 *
 * This function takes a vector \c v and a corresponding index vector \c ind,
 * and permutes the elements of \c v such that \c v[ind[i]] is moved to become
 * \c v[i] after the function is executed.
 *
 * </para><para>
 * It is an error to call this function with an index vector that does not
 * represent a valid permutation. Each element in the index vector must be
 * between 0 and the length of the vector minus one (inclusive), and each such
 * element must appear only once. The function does not attempt to validate the
 * index vector.
 *
 * </para><para>
 * The index vector that this function takes is compatible with the index vector
 * returned from \ref igraph_vector_sort_ind(); passing in the index vector
 * from \ref igraph_vector_sort_ind() will sort the original vector.
 *
 * </para><para>
 * As a special case, this function allows the index vector to be \em shorter
 * than the vector being permuted, in which case the elements whose indices do
 * not occur in the index vector will be removed from the vector.
 *
 * \param v    the vector to permute
 * \param ind  the index vector
 *
 * \return Error code:
 *         \c IGRAPH_ENOMEM if there is not enough memory.
 *
 * Time complexity: O(n), the size of the vector.
 */
igraph_error_t FUNCTION(igraph_vector, permute)(TYPE(igraph_vector) *v, const igraph_vector_int_t *index) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    IGRAPH_ASSERT(index != NULL);
    IGRAPH_ASSERT(index->stor_begin != NULL);
    IGRAPH_ASSERT(FUNCTION(igraph_vector, size)(v) >= igraph_vector_int_size(index));

    TYPE(igraph_vector) v_copy;
    BASE *v_ptr;
    igraph_integer_t *ind_ptr;

    /* There is a more space-efficient algorithm that needs O(1) space only,
     * but it messes up the index vector, which we don't want */

    IGRAPH_CHECK(FUNCTION(igraph_vector, init)(&v_copy, igraph_vector_int_size(index)));
    IGRAPH_FINALLY(FUNCTION(igraph_vector, destroy), &v_copy);

    for (
        v_ptr = v_copy.stor_begin, ind_ptr = index->stor_begin;
        ind_ptr < index->end;
        v_ptr++, ind_ptr++
    ) {
        *v_ptr = VECTOR(*v)[*ind_ptr];
    }

    IGRAPH_CHECK(FUNCTION(igraph_vector, update)(v, &v_copy));

    FUNCTION(igraph_vector, destroy)(&v_copy);
    IGRAPH_FINALLY_CLEAN(1);

    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_sort_cmp
 * \brief Internal comparison function of vector elements, used by \ref igraph_vector_sort().
 */

static int FUNCTION(igraph_vector, sort_cmp)(const void *a, const void *b) {
    const BASE *da = (const BASE *) a;
    const BASE *db = (const BASE *) b;

    return (*da > *db) - (*da < *db);
}

/**
 * \ingroup vector
 * \function igraph_vector_reverse_sort_cmp
 * \brief Internal comparison function of vector elements, used by \ref igraph_vector_reverse_sort().
 */

static int FUNCTION(igraph_vector, reverse_sort_cmp)(const void *a, const void *b) {
    const BASE *da = (const BASE *) a;
    const BASE *db = (const BASE *) b;

    return (*da < *db) - (*da > *db);
}

/**
 * \ingroup vector
 * \function igraph_vector_sort
 * \brief Sorts the elements of the vector into ascending order.
 *
 * </para><para>
 * If the vector contains any NaN values, the resulting ordering of
 * NaN values is undefined and may appear anywhere in the vector.
 * \param v Pointer to an initialized vector object.
 *
 * Time complexity:
 * O(n log n) for n elements.
 */

void FUNCTION(igraph_vector, sort)(TYPE(igraph_vector) *v) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    igraph_qsort(v->stor_begin, FUNCTION(igraph_vector, size)(v),
                 sizeof(BASE), FUNCTION(igraph_vector, sort_cmp));
}

/**
 * \ingroup vector
 * \function igraph_vector_reverse_sort
 * \brief Sorts the elements of the vector into descending order.
 *
 * </para><para>
 * If the vector contains any NaN values, the resulting ordering of
 * NaN values is undefined and may appear anywhere in the vector.
 * \param v Pointer to an initialized vector object.
 *
 * Time complexity:
 * O(n log n) for n elements.
 */

void FUNCTION(igraph_vector, reverse_sort)(TYPE(igraph_vector) *v) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    igraph_qsort(v->stor_begin, FUNCTION(igraph_vector, size)(v),
                 sizeof(BASE), FUNCTION(igraph_vector, reverse_sort_cmp));
}

/**
 * Ascending comparison function passed to qsort from  igraph_vector_sort_ind
 */
static int FUNCTION(igraph_vector, i_sort_ind_cmp_asc)(const void *p1, const void *p2) {
    BASE **pa = (BASE **) p1;
    BASE **pb = (BASE **) p2;
    if ( **pa < **pb ) {
        return -1;
    }
    if ( **pa > **pb) {
        return 1;
    }
    return 0;
}

/**
 * Descending comparison function passed to qsort from  igraph_vector_sort_ind
 */
static int FUNCTION(igraph_vector, i_sort_ind_cmp_desc)(const void *p1, const void *p2) {
    BASE **pa = (BASE **) p1;
    BASE **pb = (BASE **) p2;
    if ( **pa < **pb ) {
        return 1;
    }
    if ( **pa > **pb) {
        return -1;
    }
    return 0;
}

/**
 * \function igraph_vector_sort_ind
 * \brief Returns a permutation of indices that sorts a vector.
 *
 * Takes an unsorted array \c v as input and computes an array of indices
 * \p inds such that <code>v[ inds[i] ]</code>, with \c i increasing from 0,
 * is an ordered array (either ascending or descending, depending on
 * \p order). The order of indices for identical elements is not
 * defined. If the vector contains any NaN values, the ordering of
 * NaN values is undefined.
 *
 * \param v the array to be sorted
 * \param inds the output array of indices. This must be initialized,
 *        but will be resized
 * \param order whether the output array should be sorted in ascending
 *        or descending order. Use \c IGRAPH_ASCENDING for ascending and
 *        \c IGRAPH_DESCENDING for descending order.
 * \return Error code.
 *
 * This routine uses igraph's built-in qsort routine.
 * Algorithm: 1) create an array of pointers to the elements of v. 2)
 * Pass this array to qsort. 3) after sorting the difference between
 * the pointer value and the first pointer value gives its original
 * position in the array. Use this to set the values of inds.
 */

igraph_error_t FUNCTION(igraph_vector, sort_ind)(
        const TYPE(igraph_vector) *v,
        igraph_vector_int_t *inds,
        igraph_order_t order) {

    igraph_integer_t i, n = FUNCTION(igraph_vector, size)(v);
    BASE **vind, *first;
    IGRAPH_CHECK(igraph_vector_int_resize(inds, n));
    if (n == 0) {
        return IGRAPH_SUCCESS;
    }
    vind = IGRAPH_CALLOC(n, BASE*);
    if (vind == 0) {
        IGRAPH_ERROR("igraph_vector_sort_ind failed", IGRAPH_ENOMEM); /* LCOV_EXCL_LINE */
    }
    for (i = 0; i < n; i++) {
        vind[i] = &VECTOR(*v)[i];
    }
    first = vind[0];
    if (order == IGRAPH_ASCENDING) {
        igraph_qsort(vind, n, sizeof(BASE*), FUNCTION(igraph_vector, i_sort_ind_cmp_asc));
    } else {
        igraph_qsort(vind, n, sizeof(BASE*), FUNCTION(igraph_vector, i_sort_ind_cmp_desc));
    }
    for (i = 0; i < n; i++) {
        VECTOR(*inds)[i] = vind[i] - first;
    }
    IGRAPH_FREE(vind);
    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_qsort_ind
 * \brief Returns a permutation of indices that sorts a vector (deprecated alias).
 *
 * \deprecated-by igraph_vector_sort_ind 0.10.14
 */
igraph_error_t FUNCTION(igraph_vector, qsort_ind)(const TYPE(igraph_vector) *v,
                                                 igraph_vector_int_t *inds, igraph_order_t order) {
    return FUNCTION(igraph_vector, sort_ind)(v, inds, order);
}

/**
 * \function igraph_vector_lex_cmp
 * \brief Lexicographical comparison of two vectors (type-safe variant).
 *
 * If the elements of two vectors match but one is shorter, the shorter
 * one comes first. Thus {1, 3} comes after {1, 2, 3}, but before {1, 3, 4}.
 *
 * </para><para>
 * This function is typically used together with \ref igraph_vector_list_sort().
 *
 * \param lhs Pointer to the first vector.
 * \param rhs Pointer to the second vector.
 * \return -1 if \p lhs is lexicographically smaller,
 *         0 if \p lhs and \p rhs are equal, else 1.
 * \sa \ref igraph_vector_lex_cmp_untyped() for an untyped variant of this
 *     function, or \ref igraph_vector_colex_cmp() to compare vectors starting from
 *     the last element.
 *
 * Time complexity: O(n), the number of elements in the smaller vector.
 *
 * \example examples/simple/igraph_vector_int_list_sort.c
 */
int FUNCTION(igraph_vector, lex_cmp)(
    const TYPE(igraph_vector) *lhs, const TYPE(igraph_vector) *rhs
) {
    igraph_integer_t i, sa, sb;
    const TYPE(igraph_vector) *a = lhs, *b = rhs;

    sa = FUNCTION(igraph_vector, size)(a);
    sb = FUNCTION(igraph_vector, size)(b);

    for (i = 0; i < sa; i++) {
        if (i >= sb) {
            /* b is shorter, and equal to the first part of a */
            return 1;
        }
        if (VECTOR(*a)[i] < VECTOR(*b)[i]) {
            return -1;
        }
        if (VECTOR(*a)[i] > VECTOR(*b)[i]) {
            return 1;
        }
    }
    if (i == sb) {
        return 0;
    }
    /* a is shorter, and equal to the first part of b */
    return -1;
}

/**
 * \function igraph_vector_lex_cmp_untyped
 * \brief Lexicographical comparison of two vectors (non-type-safe).
 *
 * </para><para>
 * If the elements of two vectors match but one is shorter, the shorter
 * one comes first. Thus {1, 3} comes after {1, 2, 3}, but before {1, 3, 4}.
 *
 * </para><para>
 * This function is typically used together with \ref igraph_vector_ptr_sort().
 *
 * \param lhs Pointer to a pointer to the first vector (interpreted as an <code>igraph_vector_t **</code>).
 * \param rhs Pointer to a pointer to the second vector (interpreted as an <code>igraph_vector_t **</code>).
 * \return -1 if \p lhs is lexicographically smaller,
 *         0 if \p lhs and \p rhs are equal, else 1.
 * \sa \ref igraph_vector_lex_cmp() for a type-safe variant of this
 *     function, or \ref igraph_vector_colex_cmp_untyped() to compare vectors starting from
 *     the last element.
 *
 * Time complexity: O(n), the number of elements in the smaller vector.
 */
int FUNCTION(igraph_vector, lex_cmp_untyped)(const void *lhs, const void *rhs) {
    const TYPE(igraph_vector) *a = * (TYPE(igraph_vector) **) lhs;
    const TYPE(igraph_vector) *b = * (TYPE(igraph_vector) **) rhs;
    return FUNCTION(igraph_vector, lex_cmp)(a, b);
}

/**
 * \function igraph_vector_colex_cmp
 * \brief Colexicographical comparison of two vectors.
 *
 * This comparison starts from the last element of both vectors and
 * moves backward. If the elements of two vectors match but one is
 * shorter, the shorter one comes first. Thus {1, 2} comes after {3, 2, 1},
 * but before {0, 1, 2}.
 *
 * </para><para>
 * This function is typically used together with \ref igraph_vector_list_sort().
 *
 * \param lhs Pointer to a pointer to the first vector.
 * \param rhs Pointer to a pointer to the second vector.
 * \return -1 if \p lhs in reverse order is
 *         lexicographically smaller than the reverse of \p rhs,
 *         0 if \p lhs and \p rhs are equal, else 1.
 * \sa \ref igraph_vector_colex_cmp_untyped() for an untyped variant of this
 *     function, or \ref igraph_vector_lex_cmp() to compare vectors starting from
 *     the first element.
 *
 * Time complexity: O(n), the number of elements in the smaller vector.
 *
 * \example examples/simple/igraph_vector_int_list_sort.c
 */
int FUNCTION(igraph_vector, colex_cmp)(
    const TYPE(igraph_vector) *lhs, const TYPE(igraph_vector) *rhs
) {
    igraph_integer_t i, sa, sb, rai, rbi;
    const TYPE(igraph_vector) *a = lhs, *b = rhs;

    sa = FUNCTION(igraph_vector, size)(a);
    sb = FUNCTION(igraph_vector, size)(b);

    for (i = 0; i < sa; i++) {
        if (i >= sb) {
            /* b is shorter, and equal to the last part of a */
            return 1;
        }
        /* use reversed indexes */
        rai = sa - i - 1;
        rbi = sb - i - 1;
        if (VECTOR(*a)[rai] < VECTOR(*b)[rbi]) {
            return -1;
        }
        if (VECTOR(*a)[rai] > VECTOR(*b)[rbi]) {
            return 1;
        }
    }
    if (i == sb) {
        return 0;
    }
    /* a is shorter, and equal to the last part of b */
    return -1;
}

/**
 * \function igraph_vector_colex_cmp_untyped
 * \brief Colexicographical comparison of two vectors.
 *
 * </para><para>
 * This comparison starts from the last element of both vectors and
 * moves backward. If the elements of two vectors match but one is
 * shorter, the shorter one comes first. Thus {1, 2} comes after {3, 2, 1},
 * but before {0, 1, 2}.
 *
 * </para><para>
 * This function is typically used together with \ref igraph_vector_ptr_sort().
 *
 * \param lhs Pointer to a pointer to the first vector (interpreted as an <code>igraph_vector_t **</code>).
 * \param rhs Pointer to a pointer to the second vector (interpreted as an <code>igraph_vector_t **</code>).
 * \return -1 if \p lhs in reverse order is
 *         lexicographically smaller than the reverse of \p rhs,
 *         0 if \p lhs and \p rhs are equal, else 1.
 * \sa \ref igraph_vector_colex_cmp() for a type-safe variant of this
 *     function, \ref igraph_vector_lex_cmp_untyped() to compare vectors starting from
 *     the first element.
 *
 * Time complexity: O(n), the number of elements in the smaller vector.
 */
int FUNCTION(igraph_vector, colex_cmp_untyped)(const void *lhs, const void *rhs) {
    const TYPE(igraph_vector) *a = * (TYPE(igraph_vector) **) lhs;
    const TYPE(igraph_vector) *b = * (TYPE(igraph_vector) **) rhs;
    return FUNCTION(igraph_vector, colex_cmp)(a, b);
}

#endif /*NOTORDERED*/

/**
 * \ingroup vector
 * \function igraph_vector_resize
 * \brief Resize the vector.
 *
 * </para><para>
 * Note that this function does not free any memory, just sets the
 * size of the vector to the given one. It can on the other hand
 * allocate more memory if the new size is larger than the previous
 * one. In this case the newly appeared elements in the vector are
 * \em not set to zero, they are uninitialized.
 * \param v The vector object
 * \param new_size The new size of the vector.
 * \return Error code,
 *         \c IGRAPH_ENOMEM if there is not enough
 *         memory. Note that this function \em never returns an error
 *         if the vector is made smaller.
 * \sa \ref igraph_vector_reserve() for allocating memory for future
 * extensions of a vector. \ref igraph_vector_resize_min() for
 * deallocating the unnneded memory for a vector.
 *
 * Time complexity: O(1) if the new
 * size is smaller, operating system dependent if it is larger. In the
 * latter case it is usually around
 * O(n),
 * n is the new size of the vector.
 */

igraph_error_t FUNCTION(igraph_vector, resize)(TYPE(igraph_vector)* v, igraph_integer_t new_size) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    IGRAPH_CHECK(FUNCTION(igraph_vector, reserve)(v, new_size));
    v->end = v->stor_begin + new_size;
    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_resize_min
 * \brief Deallocate the unused memory of a vector.
 *
 * This function attempts to deallocate the unused reserved storage
 * of a vector. If it succeeds, \ref igraph_vector_size() and
 * \ref igraph_vector_capacity() will be the same. The data in the
 * vector is always preserved, even if deallocation is not successful.
 *
 * \param v Pointer to an initialized vector.
 *
 * \sa \ref igraph_vector_resize(), \ref igraph_vector_reserve().
 *
 * Time complexity: operating system dependent, O(n) at worst.
 */

void FUNCTION(igraph_vector, resize_min)(TYPE(igraph_vector) *v) {
    igraph_integer_t size;
    BASE *tmp;
    if (v->stor_end == v->end) {
        return;
    }

    size = (v->end - v->stor_begin);
    tmp = IGRAPH_REALLOC(v->stor_begin, size, BASE);

    if (tmp != NULL) {
        v->stor_begin = tmp;
        v->stor_end = v->end = v->stor_begin + size;
    }
}

#ifndef NOTORDERED

/* We will use x != x for NaN checks below and Clang does not like it unless
 * we disable a warning */

#ifdef __clang__
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wtautological-compare"
#endif

/**
 * \ingroup vector
 * \function igraph_vector_max
 * \brief Largest element of a vector.
 *
 * The vector must not be empty.
 *
 * \param v The vector object.
 * \return The maximum element of \p v, or NaN if any element is NaN.
 *
 * Time complexity: O(n), the number of elements.
 */
BASE FUNCTION(igraph_vector, max)(const TYPE(igraph_vector) *v) {
    BASE max;
    BASE *ptr;
    IGRAPH_ASSERT(!FUNCTION(igraph_vector, empty)(v));
    max = *(v->stor_begin);
#if defined(BASE_IGRAPH_REAL)
    if (isnan(max)) { return max; }; /* Result is NaN */
#endif
    ptr = v->stor_begin + 1;
    while (ptr < v->end) {
        if ((*ptr) > max) {
            max = *ptr;
        }
#if defined(BASE_IGRAPH_REAL)
        else if (isnan(*ptr))
            return *ptr; /* Result is NaN */
#endif
        ptr++;
    }
    return max;
}


/**
 * \ingroup vector
 * \function igraph_vector_which_max
 * \brief Gives the index of the maximum element of the vector.
 *
 * The vector must not be empty. If the largest
 * element is not unique, then the index of the first is returned.
 * If the vector contains NaN values, the index of the first NaN value
 * is returned.
 *
 * \param v The vector object.
 * \return The index of the first maximum element.
 *
 * Time complexity: O(n), n is the size of the vector.
 */
igraph_integer_t FUNCTION(igraph_vector, which_max)(const TYPE(igraph_vector) *v) {
    BASE *max;
    BASE *ptr;
    IGRAPH_ASSERT(!FUNCTION(igraph_vector, empty)(v));
    max = ptr = v->stor_begin;
#if defined(BASE_IGRAPH_REAL)
    if (isnan(*ptr)) { return ptr - v->stor_begin; } /* Result is NaN */
#endif
    ptr++;
    while (ptr < v->end) {
        if (*ptr > *max) {
            max = ptr;
        }
#if defined(BASE_IGRAPH_REAL)
        else if (isnan(*ptr)) {
            return ptr - v->stor_begin; /* Result is NaN */
        }
#endif
        ptr++;
    }
    return max - v->stor_begin;
}

/**
 * \ingroup vector
 * \function igraph_vector_min
 * \brief Smallest element of a vector.
 *
 * The vector must not be empty.
 *
 * \param v The input vector.
 * \return The smallest element of \p v, or NaN if any element is NaN.
 *
 * Time complexity: O(n), the number of elements.
 */

BASE FUNCTION(igraph_vector, min)(const TYPE(igraph_vector) *v) {
    BASE min;
    BASE *ptr;
    IGRAPH_ASSERT(!FUNCTION(igraph_vector, empty)(v));
    min = *(v->stor_begin);
#if defined(BASE_IGRAPH_REAL)
    if (isnan(min)) { return min; }; /* Result is NaN */
#endif
    ptr = v->stor_begin + 1;
    while (ptr < v->end) {
        if ((*ptr) < min) {
            min = *ptr;
        }
#if defined(BASE_IGRAPH_REAL)
        else if (isnan(*ptr)) {
            return *ptr; /* Result is NaN */
        }
#endif
        ptr++;
    }
    return min;
}

/**
 * \ingroup vector
 * \function igraph_vector_which_min
 * \brief Index of the smallest element.
 *
 * The vector must not be empty. If the smallest element
 * is not unique, then the index of the first is returned. If the vector
 * contains NaN values, the index of the first NaN value is returned.
 *
 * \param v The input vector.
 * \return Index of the smallest element.
 *
 * Time complexity: O(n), the number of elements.
 */
igraph_integer_t FUNCTION(igraph_vector, which_min)(const TYPE(igraph_vector)* v) {
    BASE *min;
    BASE *ptr;
    IGRAPH_ASSERT(!FUNCTION(igraph_vector, empty)(v));
    min = ptr = v->stor_begin;
#if defined(BASE_IGRAPH_REAL)
    if (isnan(*ptr)) { return ptr - v->stor_begin; } /* Result is NaN */
#endif
    ptr++;
    while (ptr < v->end) {
        if (*ptr < *min) {
            min = ptr;
        }
#if defined(BASE_IGRAPH_REAL)
        else if (isnan(*ptr)) {
            return ptr - v->stor_begin; /* Result is NaN */
        }
#endif
        ptr++;
    }
    return min - v->stor_begin;
}

#ifdef __clang__
#pragma clang diagnostic pop
#endif

#endif

/**
 * \ingroup vector
 * \function igraph_vector_init_array
 * \brief Initializes a vector from an ordinary C array (constructor).
 *
 * \param v Pointer to an uninitialized vector object.
 * \param data A regular C array.
 * \param length The length of the C array.
 * \return Error code:
 *         \c IGRAPH_ENOMEM if there is not enough memory.
 *
 * Time complexity: operating system specific, usually
 * O(\p length).
 */

igraph_error_t FUNCTION(igraph_vector, init_array)(
        TYPE(igraph_vector) *v, const BASE *data, igraph_integer_t length) {

    IGRAPH_CHECK(FUNCTION(igraph_vector, init)(v, length));

    /* Note: memcpy() behaviour is undefined if data==NULL, even if length==0. */
    if (length > 0) {
        memcpy(v->stor_begin, data, length * sizeof(BASE));
    }

    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_copy_to
 * \brief Copies the contents of a vector to a C array.
 *
 * </para><para>
 * The C array should have sufficient length.
 * \param v The vector object.
 * \param to The C array.
 *
 * Time complexity: O(n),
 * n is the size of the vector.
 */

void FUNCTION(igraph_vector, copy_to)(const TYPE(igraph_vector) *v, BASE *to) {

    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    if (v->end != v->stor_begin) {
        memcpy(to, v->stor_begin, sizeof(BASE) * (v->end - v->stor_begin));
    }
}

/**
 * \ingroup vector
 * \function igraph_vector_init_copy
 * \brief Initializes a vector from another vector object (constructor).
 *
 * </para><para>
 * The contents of the existing vector object will be copied to
 * the new one.
 * \param to Pointer to a not yet initialized vector object.
 * \param from The original vector object to copy.
 * \return Error code:
 *         \c IGRAPH_ENOMEM if there is not enough memory.
 *
 * Time complexity: operating system dependent, usually
 * O(n),
 * n is the size of the vector.
 */

igraph_error_t FUNCTION(igraph_vector, init_copy)(
    TYPE(igraph_vector) *to, const TYPE(igraph_vector) *from
) {
    igraph_integer_t from_size;

    IGRAPH_ASSERT(from != NULL);
    IGRAPH_ASSERT(from->stor_begin != NULL);

    from_size = FUNCTION(igraph_vector, size)(from);
    IGRAPH_CHECK(FUNCTION(igraph_vector, init)(to, from_size));

    memcpy(to->stor_begin, from->stor_begin, from_size * sizeof(BASE));

    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_copy
 * \brief Initializes a vector from another vector object (deprecated alias).
 *
 * \deprecated-by igraph_vector_init_copy 0.10
 */

igraph_error_t FUNCTION(igraph_vector, copy)(TYPE(igraph_vector) *to,
                                  const TYPE(igraph_vector) *from) {
    return FUNCTION(igraph_vector, init_copy)(to, from);
}

/**
 * \ingroup vector
 * \function igraph_vector_sum
 * \brief Calculates the sum of the elements in the vector.
 *
 * For the empty vector 0 is returned.
 *
 * \param v The vector object.
 * \return The sum of the elements.
 *
 * Time complexity: O(n), the size of
 * the vector.
 */

BASE FUNCTION(igraph_vector, sum)(const TYPE(igraph_vector) *v) {
    BASE res = ZERO;
    BASE *p;
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    for (p = v->stor_begin; p < v->end; p++) {
#ifdef SUM
        SUM(res, res, *p);
#else
        res += *p;
#endif
    }
    return res;
}

igraph_real_t FUNCTION(igraph_vector, sumsq)(const TYPE(igraph_vector) *v) {
    igraph_real_t res = 0.0;
    BASE *p;
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    for (p = v->stor_begin; p < v->end; p++) {
#ifdef SQ
        res += SQ(*p);
#else
        res += (*p) * (*p);
#endif
    }
    return res;
}

/**
 * \ingroup vector
 * \function igraph_vector_prod
 * \brief Calculates the product of the elements in the vector.
 *
 * </para><para>
 * For the empty vector one (1) is returned.
 * \param v The vector object.
 * \return The product of the elements.
 *
 * Time complexity: O(n), the size of
 * the vector.
 */

BASE FUNCTION(igraph_vector, prod)(const TYPE(igraph_vector) *v) {
    BASE res = ONE;
    BASE *p;
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    for (p = v->stor_begin; p < v->end; p++) {
#ifdef PROD
        PROD(res, res, *p);
#else
        res *= *p;
#endif
    }
    return res;
}

/**
 * \ingroup vector
 * \function igraph_vector_cumsum
 * \brief Calculates the cumulative sum of the elements in the vector.
 *
 * </para><para>
 * \param to An initialized vector object that will store the cumulative
 *           sums. Element i of this vector will store the sum of the elements
 *           of the 'from' vector, up to and including element i.
 * \param from The input vector.
 * \return Error code.
 *
 * Time complexity: O(n), the size of the vector.
 */

igraph_error_t FUNCTION(igraph_vector, cumsum)(TYPE(igraph_vector) *to,
                                    const TYPE(igraph_vector) *from) {
    BASE res = ZERO;
    BASE *p, *p2;

    IGRAPH_ASSERT(from != NULL);
    IGRAPH_ASSERT(from->stor_begin != NULL);
    IGRAPH_ASSERT(to != NULL);
    IGRAPH_ASSERT(to->stor_begin != NULL);

    IGRAPH_CHECK(FUNCTION(igraph_vector, resize)(to, FUNCTION(igraph_vector, size)(from)));

    for (p = from->stor_begin, p2 = to->stor_begin; p < from->end; p++, p2++) {
#ifdef SUM
        SUM(res, res, *p);
#else
        res += *p;
#endif
        *p2 = res;
    }

    return IGRAPH_SUCCESS;
}

#ifndef NOTORDERED

/**
 * \ingroup vector
 * \function igraph_vector_init_seq
 * \brief Initializes a vector with a sequence, inclusive endpoints (deprecated).
 *
 * </para><para>
 * The vector will contain the numbers \p from, \p from+1, ..., \p to. Note that
 * both endpoints are \em inclusive, contrary to typical usage of ranges in C.
 *
 * \deprecated-by igraph_vector_init_range 0.10.0
 *
 * \param v Pointer to an uninitialized vector object.
 * \param from The lower limit in the sequence (inclusive).
 * \param to The upper limit in the sequence (inclusive).
 * \return Error code:
 *         \c IGRAPH_ENOMEM: out of memory.
 *
 * Time complexity: O(n), the number
 * of elements in the vector.
 */

igraph_error_t FUNCTION(igraph_vector, init_seq)(TYPE(igraph_vector) *v, BASE from, BASE to) {
    BASE *p;
    IGRAPH_CHECK(FUNCTION(igraph_vector, init)(v, (to - from + 1)));

    for (p = v->stor_begin; p < v->end; p++) {
        *p = from++;
    }

    return IGRAPH_SUCCESS;
}

/**
 * \ingroup vector
 * \function igraph_vector_init_range
 * \brief Initializes a vector with a range.
 *
 * </para><para>
 * The vector will contain the numbers \p start, \p start+1, ..., \p end-1. Note
 * that the range is closed from the left and open from the right, according to
 * C conventions.
 *
 * \param v Pointer to an uninitialized vector object.
 * \param start The lower limit in the range (inclusive).
 * \param end The upper limit in the range (exclusive).
 * \return Error code:
 *         \c IGRAPH_ENOMEM: out of memory.
 *
 * Time complexity: O(n), the number of elements in the vector.
 */

igraph_error_t FUNCTION(igraph_vector, init_range)(TYPE(igraph_vector) *v, BASE start, BASE end) {
    BASE *p;
    IGRAPH_CHECK(FUNCTION(igraph_vector, init)(v, (end - start)));

    for (p = v->stor_begin; p < v->end; p++) {
        *p = start;
        start = start + ONE;
    }

    return IGRAPH_SUCCESS;
}

#endif

/**
 * \ingroup vector
 * \function igraph_vector_remove_section
 * \brief Deletes a section from a vector.
 *
 * </para><para>
 * \param v The vector object.
 * \param from The position of the first element to remove.
 * \param to The position of the first element \em not to remove.
 *
 * Time complexity: O(n-from),
 * n is the number of elements in the
 * vector.
 */

void FUNCTION(igraph_vector, remove_section)(
        TYPE(igraph_vector) *v, igraph_integer_t from, igraph_integer_t to) {
    igraph_integer_t size = FUNCTION(igraph_vector, size)(v);

    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);

    if (from < 0) {
        from = 0;
    }

    if (to > size) {
        to = size;
    }

    if (to > from) {
        memmove(v->stor_begin + from, v->stor_begin + to,
                sizeof(BASE) * (v->end - v->stor_begin - to));
        v->end -= (to - from);
    }
}

/**
 * \ingroup vector
 * \function igraph_vector_remove
 * \brief Removes a single element from a vector.
 *
 * Note that this function does not do range checking.
 * \param v The vector object.
 * \param elem The position of the element to remove.
 *
 * Time complexity: O(n-elem),
 * n is the number of elements in the
 * vector.
 */

void FUNCTION(igraph_vector, remove)(TYPE(igraph_vector) *v, igraph_integer_t elem) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    FUNCTION(igraph_vector, remove_section)(v, elem, elem + 1);
}

/**
 * \ingroup vector
 * \function igraph_vector_remove_fast
 * \brief Removes a single element from a vector, \em not keeping the order of the remaining elements.
 *
 * This function removes the element with the given element from the vector by
 * swapping it with the last element and then popping it off. You can use this
 * function instead of \ref igraph_vector_remove() to gain some speed if the
 * order of elements does not matter.
 *
 * </para><para>
 * Note that this function does not do range checking.
 *
 * \param v The vector object.
 * \param elem The position of the element to remove.
 *
 * Time complexity: O(1).
 */

void FUNCTION(igraph_vector, remove_fast)(TYPE(igraph_vector) *v, igraph_integer_t elem) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);

    igraph_integer_t len = FUNCTION(igraph_vector, size)(v);
    VECTOR(*v)[elem] = VECTOR(*v)[len - 1];
    FUNCTION(igraph_vector, pop_back)(v);
}

/**
 * \ingroup vector
 * \function igraph_vector_move_interval
 * \brief Copies a section of a vector.
 *
 * </para><para>
 * The source and the destination sections are allowed to overlap; this will
 * be handled internally by the function.
 * \param v The vector object.
 * \param begin The position of the first element to move.
 * \param end The position of the first element \em not to move.
 * \param to The target position.
 * \return Error code, the current implementation always returns with
 *    success.
 *
 * Time complexity: O(end-begin).
 */

igraph_error_t FUNCTION(igraph_vector, move_interval)(TYPE(igraph_vector) *v,
        igraph_integer_t begin, igraph_integer_t end, igraph_integer_t to) {
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    memmove(v->stor_begin + to, v->stor_begin + begin,
           sizeof(BASE) * (end - begin));

    return IGRAPH_SUCCESS;
}

/**
 * \deprecated-by igraph_vector_move_interval 0.10.0
 */
igraph_error_t FUNCTION(igraph_vector, move_interval2)(TYPE(igraph_vector) *v,
        igraph_integer_t begin, igraph_integer_t end, igraph_integer_t to) {
    return FUNCTION(igraph_vector, move_interval)(v, begin, end, to);
}

#ifndef NOTORDERED

/**
 * \ingroup vector
 * \function igraph_vector_isininterval
 * \brief Checks if all elements of a vector are in the given interval.
 *
 * \param v The vector object.
 * \param low The lower limit of the interval (inclusive).
 * \param high The higher limit of the interval (inclusive).
 * \return True if the vector is empty or all vector elements
 *   are in the interval, false otherwise. If any element is NaN, it will
 *   return false.
 *
 * Time complexity: O(n), the number of elements in the vector.
 */

igraph_bool_t FUNCTION(igraph_vector, isininterval)(const TYPE(igraph_vector) *v,
        BASE low,
        BASE high) {
    BASE *ptr;
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    for (ptr = v->stor_begin; ptr < v->end; ptr++) {
        /* Note that the following is not equivalent to *ptr < low || *ptr > high
         * when *ptr is NaN! */
        if (!(*ptr >= low && *ptr <= high)) {
            return 0;
        }
    }
    return 1;
}

/**
 * \ingroup vector
 * \function igraph_vector_any_smaller
 * \brief Checks if any element of a vector is smaller than a limit.
 *
 * \param v The \type igraph_vector_t object.
 * \param limit The limit.
 * \return True if the vector contains at least one
 *   smaller element than \p limit, false otherwise.
 *
 * Time complexity: O(n), the number of elements in the vector.
 */

igraph_bool_t FUNCTION(igraph_vector, any_smaller)(const TYPE(igraph_vector) *v,
        BASE limit) {
    BASE *ptr;
    IGRAPH_ASSERT(v != NULL);
    IGRAPH_ASSERT(v->stor_begin != NULL);
    for (ptr = v->stor_begin; ptr < v->end; ptr++) {
        if (*ptr < limit) {
            return 1;
        }
    }
    return 0;
}

#endif

/**
 * \ingroup vector
 * \function igraph_vector_all_e
 * \brief Are all elements equal?
 *
 * Checks element-wise equality of two vectors. For vectors containing floating
 * point values, consider using \ref igraph_matrix_all_almost_e().
 *
 * \param lhs The first vector.
 * \param rhs The second vector.
 * \return True if the elements in the \p lhs are all
 *    equal to the corresponding elements in \p rhs. Returns
 *    false if the lengths of the vectors don't match.
 *
 * Time complexity: O(n), the length of the vectors.
 */

igraph_bool_t FUNCTION(igraph_vector, all_e)(const TYPE(igraph_vector) *lhs,
                                  const TYPE(igraph_vector) *rhs) {
    igraph_integer_t i, s;
    IGRAPH_ASSERT(lhs != 0);
    IGRAPH_ASSERT(rhs != 0);
    IGRAPH_ASSERT(lhs->stor_begin != 0);
    IGRAPH_ASSERT(rhs->stor_begin != 0);

    s = FUNCTION(igraph_vector, size)(lhs);
    if (s != FUNCTION(igraph_vector, size)(rhs)) {
        return false;
    } else {
        for (i = 0; i < s; i++) {
            BASE l = VECTOR(*lhs)[i];
            BASE r = VECTOR(*rhs)[i];
#ifdef EQ
            if (!EQ(l, r)) {
#else
            if (l != r) {
#endif
                return false;
            }
        }
        return true;
    }
}

/**
 * \ingroup vector
 * \function igraph_vector_is_equal
 * \brief Are all elements equal?
 *
 * This is an alias of \ref igraph_vector_all_e() with a more intuitive name.
 *
 * \param lhs The first vector.
 * \param rhs The second vector.
 * \return True if the elements in the \p lhs are all
 *    equal to the corresponding elements in \p rhs. Returns
 *    false if the lengths of the vectors don't match.
 *
 * Time complexity: O(n), the length of the vectors.
 */

igraph_bool_t FUNCTION(igraph_vector, is_equal)(const TYPE(igraph_vector) *lhs,
                                     const TYPE(igraph_vector) *rhs) {
    return FUNCTION(igraph_vector, all_e)(lhs, rhs);
}

#ifndef NOTORDERED

/**
 * \ingroup vector
 * \function igraph_vector_all_l
 * \brief Are all elements less?
 *
 * \param lhs The first vector.
 * \param rhs The second vector.
 * \return True if the elements in the \p lhs are all
 *    less than the corresponding elements in \p rhs. Returns false
 *    if the lengths of the vectors don't match. If any element
 *    is NaN, it will return false.
 *
 * Time complexity: O(n), the length of the vectors.
 */

igraph_bool_t FUNCTION(igraph_vector, all_l)(const TYPE(igraph_vector) *lhs,
                                  const TYPE(igraph_vector) *rhs) {
    igraph_integer_t i, s;
    IGRAPH_ASSERT(lhs != 0);
    IGRAPH_ASSERT(rhs != 0);
    IGRAPH_ASSERT(lhs->stor_begin != 0);
    IGRAPH_ASSERT(rhs->stor_begin != 0);

    s = FUNCTION(igraph_vector, size)(lhs);
    if (s != FUNCTION(igraph_vector, size)(rhs)) {
        return false;
    } else {
        for (i = 0; i < s; i++) {
            BASE l = VECTOR(*lhs)[i];
            BASE r = VECTOR(*rhs)[i];
            if (l >= r) {
                return false;
            }
        }
        return true;
    }
}

/**
 * \ingroup vector
 * \function igraph_vector_all_g
 * \brief Are all elements greater?
 *
 * \param lhs The first vector.
 * \param rhs The second vector.
 * \return True if the elements in the \p lhs are all
 *    greater than the corresponding elements in \p rhs. Returns false
 *    if the lengths of the vectors don't match. If any element
 *    is NaN, it will return false.
 *
 * Time complexity: O(n), the length of the vectors.
 */

igraph_bool_t FUNCTION(igraph_vector, all_g)(const TYPE(igraph_vector) *lhs,
                                  const TYPE(igraph_vector) *rhs) {

    igraph_integer_t i, s;
    IGRAPH_ASSERT(lhs != 0);
    IGRAPH_ASSERT(rhs != 0);
    IGRAPH_ASSERT(lhs->stor_begin != 0);
    IGRAPH_ASSERT(rhs->stor_begin != 0);

    s = FUNCTION(igraph_vector, size)(lhs);
    if (s != FUNCTION(igraph_vector, size)(rhs)) {
        return false;
    } else {
        for (i = 0; i < s; i++) {
            BASE l = VECTOR(*lhs)[i];
            BASE r = VECTOR(*rhs)[i];
            if (l <= r) {
                return false;
            }
        }
        return true;
    }
}

/**
 * \ingroup vector
 * \function igraph_vector_all_le
 * \brief Are all elements less or equal?
 *
 * \param lhs The first vector.
 * \param rhs The second vector.
 * \return True if the elements in the \p lhs are all
 *    less than or equal to the corresponding elements in \p
 *    rhs. Returns false if the lengths of the vectors don't
 *    match. If any element is NaN, it will return false.
 *
 * Time complexity: O(n), the length of the vectors.
 */

igraph_bool_t FUNCTION(igraph_vector, all_le)(const TYPE(igraph_vector) *lhs,
                                   const TYPE(igraph_vector) *rhs) {
    igraph_integer_t i, s;
    IGRAPH_ASSERT(lhs != 0);
    IGRAPH_ASSERT(rhs != 0);
    IGRAPH_ASSERT(lhs->stor_begin != 0);
    IGRAPH_ASSERT(rhs->stor_begin != 0);

    s = FUNCTION(igraph_vector, size)(lhs);
    if (s != FUNCTION(igraph_vector, size)(rhs)) {
        return false;
    } else {
        for (i = 0; i < s; i++) {
            BASE l = VECTOR(*lhs)[i];
            BASE r = VECTOR(*rhs)[i];
            if (l > r) {
                return false;
            }
        }
        return true;
    }
}

/**
 * \ingroup vector
 * \function igraph_vector_all_ge
 * \brief Are all elements greater or equal?
 *
 * \param lhs The first vector.
 * \param rhs The second vector.
 * \return True if the elements in the \p lhs are all
 *    greater than or equal to the corresponding elements in \p
 *    rhs. Returns false if the lengths of the vectors don't
 *    match.  If any element is NaN, it will return false.
 *
 * Time complexity: O(n), the length of the vectors.
 */

igraph_bool_t FUNCTION(igraph_vector, all_ge)(const TYPE(igraph_vector) *lhs,
                                   const TYPE(igraph_vector) *rhs) {
    igraph_integer_t i, s;
    IGRAPH_ASSERT(lhs != 0);
    IGRAPH_ASSERT(rhs != 0);
    IGRAPH_ASSERT(lhs->stor_begin != 0);
    IGRAPH_ASSERT(rhs->stor_begin != 0);

    s = FUNCTION(igraph_vector, size)(lhs);
    if (s != FUNCTION(igraph_vector, size)(rhs)) {
        return false;
    } else {
        for (i = 0; i < s; i++) {
            BASE l = VECTOR(*lhs)[i];
            BASE r = VECTOR(*rhs)[i];
            if (l < r) {
                return false;
            }
        }
        return true;
    }
}

#endif


#ifndef NOTORDERED

static igraph_bool_t FUNCTION(igraph_i_vector, binsearch_slice)(const TYPE(igraph_vector) *v,
        BASE what, igraph_integer_t *pos, igraph_integer_t start, igraph_integer_t end);

/**
 * \ingroup vector
 * \function igraph_vector_binsearch
 * \brief Finds an element by binary searching a sorted vector.
 *
 * </para><para>
 * It is assumed that the vector is sorted. If the specified element
 * (\p what) is not in the vector, then the
 * position of where it should be inserted (to keep the vector sorted)
 * is returned. If the vector contains any NaN values, the returned
 * value is undefined and \p pos may point to any position.
 *
 * \param v The \type igraph_vector_t object.
 * \param what The element to search for.
 * \param pos Pointer to an \type igraph_integer_t. This is set to the
 *   position of an instance of \p what in the
 *   vector if it is present. If \p v does not
 *   contain \p what then
 *   \p pos is set to the position to which it
 *   should be inserted (to keep the the vector sorted of course).
 * \return True if \p what is found in the vector, false otherwise.
 *
 * Time complexity: O(log(n)),
 * n is the number of elements in
 * \p v.
 */

igraph_bool_t FUNCTION(igraph_vector, binsearch)(const TYPE(igraph_vector) *v,
        BASE what, igraph_integer_t *pos) {
    return FUNCTION(igraph_i_vector, binsearch_slice)(v, what, pos,
            0, FUNCTION(igraph_vector, size)(v));
}

/**
 * \ingroup vector
 * \function igraph_vector_binsearch_slice
 * \brief Finds an element by binary searching a sorted slice of a vector.
 *
 * </para><para>
 * It is assumed that the indicated slice of the vector, from \p start to \p end,
 * is sorted. If the specified element (\p what) is not in the slice of the
 * vector, then the position of where it should be inserted (to keep the \em slice
 * sorted) is returned. Note that this means that the returned index will point
 * \em inside the slice (including its endpoints), but will not evaluate values
 * \em outside the slice. If the indicated slice contains any NaN values, the
 * returned value is undefined and \c pos may point to any position within
 * the slice.
 *
 * \param v The \type igraph_vector_t object.
 * \param what The element to search for.
 * \param pos Pointer to an \type igraph_integer_t. This is set to the position of an
 *        instance of \p what in the slice of the vector if it is present. If \p
 *        v does not contain \p what then \p pos is set to the position to which
 *        it should be inserted (to keep the the vector sorted).
 * \param start The start position of the slice to search (inclusive).
 * \param end The end position of the slice to search (exclusive).
 * \return True if \p what is found in the vector, false otherwise.
 *
 * Time complexity: O(log(n)),
 * n is the number of elements in the slice of \p v, i.e. \p end - \p start.
 */

igraph_bool_t FUNCTION(igraph_vector, binsearch_slice)(const TYPE(igraph_vector) *v,
        BASE what, igraph_integer_t *pos, igraph_integer_t start, igraph_integer_t end) {
    igraph_integer_t left  = start;
    igraph_integer_t right = end - 1;

    if (left < 0)
        IGRAPH_ERROR("Invalid start position.", IGRAPH_EINVAL);

    if (right >= FUNCTION(igraph_vector, size)(v))
        IGRAPH_ERROR("Invalid end position.", IGRAPH_EINVAL);

    if (left > right)
        IGRAPH_ERROR("Invalid slice, start position must be smaller than end position.",
                     IGRAPH_EINVAL);

    return FUNCTION(igraph_i_vector, binsearch_slice)(v, what, pos, start, end);
}

static igraph_bool_t FUNCTION(igraph_i_vector, binsearch_slice)(const TYPE(igraph_vector) *v,
        BASE what, igraph_integer_t *pos, igraph_integer_t start, igraph_integer_t end) {
    igraph_integer_t left  = start;
    igraph_integer_t right = end - 1;

    while (left <= right) {
        /* (right + left) / 2 could theoretically overflow for long vectors */
        igraph_integer_t middle = left + ((right - left) >> 1);
        if (VECTOR(*v)[middle] > what) {
            right = middle - 1;
        } else if (VECTOR(*v)[middle] < what) {
            left = middle + 1;
        } else {
            if (pos != 0) {
                *pos = middle;
            }
            return true;
        }
    }

    /* if we are here, the element was not found */
    if (pos != 0) {
        *pos = left;
    }

    return false;
}

/**
 * \ingroup vector
 * \function igraph_vector_contains_sorted
 * \brief Binary search in a sorted vector.
 *
 * It is assumed that the vector is sorted.
 *
 * \param v The \type igraph_vector_t object.
 * \param what The element to search for.
 * \return True if \p what is found in the vector, false otherwise.
 *
 * Time complexity: O(log(n)), n is the number of elements in \p v.
 */

igraph_bool_t FUNCTION(igraph_vector, contains_sorted)(const TYPE(igraph_vector) *v, BASE what) {
    igraph_integer_t left = 0;
    igraph_integer_t right = FUNCTION(igraph_vector, size)(v) - 1;

    while (left <= right) {
        /* (right + left) / 2 could theoretically overflow for long vectors */
        igraph_integer_t middle = left + ((right - left) >> 1);
        if (what < VECTOR(*v)[middle]) {
            right = middle - 1;
        } else if (what > VECTOR(*v)[middle]) {
            left = middle + 1;
        } else {
            return true;
        }
    }

    return false;
}

/**
 * \ingroup vector
 * \function igraph_vector_binsearch2
 * \brief Binary search, without returning the index.
 *
 * \deprecated-by igraph_vector_contains_sorted 0.10.14
 */
igraph_bool_t FUNCTION(igraph_vector, binsearch2)(const TYPE(igraph_vector) *v,
                                                  BASE what) {
    return FUNCTION(igraph_vector, contains_sorted)(v, what);
}

#endif

/**
 * \function igraph_vector_scale
 * \brief Multiplies all elements of a vector by a constant.
 *
 * \param v The vector.
 * \param by The constant.
 * \return Error code. The current implementation always returns with success.
 *
 * Added in version 0.2.</para><para>
 *
 * Time complexity: O(n), the number of elements in a vector.
 */

void FUNCTION(igraph_vector, scale)(TYPE(igraph_vector) *v, BASE by) {
    igraph_integer_t i;
    for (i = 0; i < FUNCTION(igraph_vector, size)(v); i++) {
#ifdef PROD
        PROD(VECTOR(*v)[i], VECTOR(*v)[i], by);
#else
        VECTOR(*v)[i] *= by;
#endif
    }
}

/**
 * \function igraph_vector_add_constant
 * \brief Add a constant to the vector.
 *
 * \p plus is added to every element of \p v. Note that overflow
 * might happen.
 * \param v The input vector.
 * \param plus The constant to add.
 *
 * Time complexity: O(n), the number of elements.
 */

void FUNCTION(igraph_vector, add_constant)(TYPE(igraph_vector) *v, BASE plus) {
    igraph_integer_t i, n = FUNCTION(igraph_vector, size)(v);
    for (i = 0; i < n; i++) {
#ifdef SUM
        SUM(VECTOR(*v)[i], VECTOR(*v)[i], plus);
#else
        VECTOR(*v)[i] += plus;
#endif
    }
}

/**
 * \function igraph_vector_contains
 * \brief Linear search in a vector.
 *
 * Check whether the supplied element is included in the vector, by
 * linear search.
 *
 * \param v The input vector.
 * \param what The element to look for.
 * \return \c true if the element is found and \c false otherwise.
 *
 * Time complexity: O(n), the length of the vector.
 */

igraph_bool_t FUNCTION(igraph_vector, contains)(const TYPE(igraph_vector) *v,
        BASE what) {
    const BASE *p = v->stor_begin;
    while (p < v->end) {
#ifdef EQ
        if (EQ(*p, what)) {
#else
        if (*p == what) {
#endif
            return true;
        }
        p++;
    }
    return false;
}

/**
 * \function igraph_vector_search
 * \brief Searches in a vector from a given position.
 *
 * The supplied element \p what is searched in vector \p v, starting
 * from element index \p from. If found then the index of the first
 * instance (after \p from) is stored in \p pos.
 *
 * \param v The input vector.
 * \param from The index to start searching from. No range checking is
 *     performed.
 * \param what The element to find.
 * \param pos If not \c NULL then the index of the found element is
 *    stored here.
 * \return Boolean, \c true if the element was found, \c false
 *   otherwise.
 *
 * Time complexity: O(m), the number of elements to search, the length
 * of the vector minus the \p from argument.
 */

igraph_bool_t FUNCTION(igraph_vector, search)(const TYPE(igraph_vector) *v,
        igraph_integer_t from, BASE what, igraph_integer_t *pos) {
    igraph_integer_t i, n = FUNCTION(igraph_vector, size)(v);
    for (i = from; i < n; i++) {
#ifdef EQ
        if (EQ(VECTOR(*v)[i], what)) {
            break;
        }
#else
        if (VECTOR(*v)[i] == what) {
            break;
        }
#endif
    }

    if (i < n) {
        if (pos != 0) {
            *pos = i;
        }
        return true;
    } else {
        return false;
    }
}

#ifndef NOTORDERED

/**
 * \function igraph_vector_filter_smaller
 * \ingroup internal
 */

igraph_error_t FUNCTION(igraph_vector, filter_smaller)(TYPE(igraph_vector) *v,
        BASE elem) {
    igraph_integer_t i = 0, n = FUNCTION(igraph_vector, size)(v);
    igraph_integer_t s;
    while (i < n && VECTOR(*v)[i] < elem) {
        i++;
    }
    s = i;

    while (s < n && VECTOR(*v)[s] == elem) {
        s++;
    }

    FUNCTION(igraph_vector, remove_section)(v, 0, i + (s - i) / 2);
    return IGRAPH_SUCCESS;
}

#endif

/**
 * \function igraph_vector_append
 * \brief Append a vector to another one.
 *
 * The target vector will be resized (except when \p from is empty).
 * \param to The vector to append to.
 * \param from The vector to append, it is kept unchanged.
 * \return Error code.
 *
 * Time complexity: O(n), the number of elements in the new vector.
 */

igraph_error_t FUNCTION(igraph_vector, append)(TYPE(igraph_vector) *to,
                                    const TYPE(igraph_vector) *from) {
    igraph_integer_t tosize, fromsize;
    igraph_integer_t newsize;

    tosize = FUNCTION(igraph_vector, size)(to);
    fromsize = FUNCTION(igraph_vector, size)(from);
    IGRAPH_SAFE_ADD(tosize, fromsize, &newsize);
    IGRAPH_CHECK(FUNCTION(igraph_vector, resize)(to, newsize));
    memcpy(to->stor_begin + tosize, from->stor_begin,
           sizeof(BASE) * fromsize);
    to->end = to->stor_begin + tosize + fromsize;

    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_get_interval
 */

igraph_error_t FUNCTION(igraph_vector, get_interval)(const TYPE(igraph_vector) *v,
        TYPE(igraph_vector) *res, igraph_integer_t from, igraph_integer_t to) {
    IGRAPH_CHECK(FUNCTION(igraph_vector, resize)(res, to - from));
    memcpy(res->stor_begin, v->stor_begin + from,
           (to - from) * sizeof(BASE));
    return IGRAPH_SUCCESS;
}

#ifndef NOTORDERED

/**
 * \function igraph_vector_maxdifference
 * \brief The maximum absolute difference of \p m1 and \p m2.
 *
 * The element with the largest absolute value in \p m1 - \p m2 is
 * returned. Both vectors must be non-empty, but they not need to have
 * the same length, the extra elements in the longer vector are ignored. If
 * any value is NaN in the shorter vector, the result will be NaN.
 * \param m1 The first vector.
 * \param m2 The second vector.
 * \return The maximum absolute difference of \p m1 and \p m2.
 *
 * Time complexity: O(n), the number of elements in the shorter
 * vector.
 */

igraph_real_t FUNCTION(igraph_vector, maxdifference)(const TYPE(igraph_vector) *m1,
        const TYPE(igraph_vector) *m2) {
    igraph_integer_t n1 = FUNCTION(igraph_vector, size)(m1);
    igraph_integer_t n2 = FUNCTION(igraph_vector, size)(m2);
    igraph_integer_t n = n1 < n2 ? n1 : n2;
    igraph_integer_t i;
    igraph_real_t diff = 0.0;

    for (i = 0; i < n; i++) {
        igraph_real_t d = fabs((igraph_real_t)(VECTOR(*m1)[i]) -
                               (igraph_real_t)(VECTOR(*m2)[i]));
        if (d > diff) {
            diff = d;
        }
    #if defined(BASE_IGRAPH_REAL)
        else if (isnan(d)) { /* Result is NaN */
            return d;
        };
    #endif
    }

    return diff;
}

#endif

/**
 * \function igraph_vector_update
 * \brief Update a vector from another one.
 *
 * After this operation the contents of \p to will be exactly the same
 * as that of \p from. The vector \p to will be resized if it was originally
 * shorter or longer than \p from.
 * \param to The vector to update.
 * \param from The vector to update from.
 * \return Error code.
 *
 * Time complexity: O(n), the number of elements in \p from.
 */

igraph_error_t FUNCTION(igraph_vector, update)(TYPE(igraph_vector) *to,
                                    const TYPE(igraph_vector) *from) {
    igraph_integer_t n = FUNCTION(igraph_vector, size)(from);
    IGRAPH_CHECK(FUNCTION(igraph_vector, resize)(to, n));
    memcpy(to->stor_begin, from->stor_begin, sizeof(BASE)*n);
    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_swap
 * \brief Swap all elements of two vectors.
 *
 * \param v1 The first vector.
 * \param v2 The second vector.
 * \return Error code.
 *
 * Time complexity: O(1).
 */

igraph_error_t FUNCTION(igraph_vector, swap)(TYPE(igraph_vector) *v1, TYPE(igraph_vector) *v2) {

    TYPE(igraph_vector) tmp;

    tmp = *v1;
    *v1 = *v2;
    *v2 = tmp;

    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_swap_elements
 * \brief Swap two elements in a vector.
 *
 * Note that currently no range checking is performed.
 * \param v The input vector.
 * \param i Index of the first element.
 * \param j Index of the second element (may be the same as the
 * first one).
 * \return Error code, currently always \c IGRAPH_SUCCESS.
 *
 * Time complexity: O(1).
 */

igraph_error_t FUNCTION(igraph_vector, swap_elements)(TYPE(igraph_vector) *v,
        igraph_integer_t i, igraph_integer_t j) {
    BASE tmp = VECTOR(*v)[i];
    VECTOR(*v)[i] = VECTOR(*v)[j];
    VECTOR(*v)[j] = tmp;

    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_reverse_section
 * \brief Reverse the elements in a section of a vector.
 *
 * \param v The input vector.
 * \param from Index of the first element to include in the reversal.
 * \param to Index of the first element \em not to include in the reversal.
 *
 * \sa igraph_vector_reverse() to reverse the entire vector.
 *
 * Time complexity: O(to - from), the number of elements to reverse.
 */

void FUNCTION(igraph_vector, reverse_section)(TYPE(igraph_vector) *v, igraph_integer_t from, igraph_integer_t to) {
    const igraph_integer_t mid = (from + to) / 2;
    for (igraph_integer_t i = from, j = to - 1; i < mid; i++, j--) {
        BASE tmp = VECTOR(*v)[i];
        VECTOR(*v)[i] = VECTOR(*v)[j];
        VECTOR(*v)[j] = tmp;
    }
}

/**
 * \function igraph_vector_reverse
 * \brief Reverse the elements of a vector.
 *
 * The first element will be last, the last element will be
 * first, etc.
 *
 * \param v The input vector.
 * \return Error code, currently always \c IGRAPH_SUCCESS.
 *
 * \sa igraph_vector_reverse_section() to reverse only a section of a vector.
 *
 * Time complexity: O(n), the number of elements.
 */

igraph_error_t FUNCTION(igraph_vector, reverse)(TYPE(igraph_vector) *v) {
    FUNCTION(igraph_vector, reverse_section)(v, 0, FUNCTION(igraph_vector, size)(v));
    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_rotate_left
 * \brief Rotates the elements of a vector to the left.
 *
 * Rotates the elements of a vector to the left by the given number of steps.
 * Element index \p n will have index 0 after the rotation.
 * For example, rotating <code>(0, 1, 2, 3, 4, 5)</code> by 2 yields
 * <code>(2, 3, 4, 5, 0, 1)</code>.
 *
 * \param v The input vector.
 * \param n The number of steps to rotate by. Passing a negative value rotates
 *    to the right.
 *
 * Time complexity: O(n), the number of elements.
 */

void FUNCTION(igraph_vector, rotate_left)(TYPE(igraph_vector) *v, igraph_integer_t n) {
    const igraph_integer_t size = FUNCTION(igraph_vector, size)(v);
    n = n % size;
    if (n < 0) n += size;
    if (n == 0) return;
    FUNCTION(igraph_vector, reverse_section)(v, 0, n);
    FUNCTION(igraph_vector, reverse_section)(v, n, size);
    FUNCTION(igraph_vector, reverse_section)(v, 0, size);
}

/**
 * \ingroup vector
 * \function igraph_vector_shuffle
 * \brief Shuffles a vector in-place using the Fisher-Yates method.
 *
 * </para><para>
 * The Fisher-Yates shuffle ensures that every permutation is
 * equally probable when using a proper randomness source. Of course
 * this does not apply to pseudo-random generators as the cycle of
 * these generators is less than the number of possible permutations
 * of the vector if the vector is long enough.
 * \param v The vector object.
 * \return Error code, currently always \c IGRAPH_SUCCESS.
 *
 * Time complexity: O(n),
 * n is the number of elements in the
 * vector.
 *
 * </para><para>
 * References:
 * \clist
 * \cli (Fisher &amp; Yates 1963)
 *   R. A. Fisher and F. Yates. \emb Statistical Tables for Biological,
 *   Agricultural and Medical Research. \eme Oliver and Boyd, 6th edition,
 *   1963, page 37.
 * \cli (Knuth 1998)
 *   D. E. Knuth. \emb Seminumerical Algorithms, \eme volume 2 of \emb The Art
 *   of Computer Programming. \eme Addison-Wesley, 3rd edition, 1998, page 145.
 * \endclist
 *
 * \example examples/simple/igraph_fisher_yates_shuffle.c
 */

igraph_error_t FUNCTION(igraph_vector, shuffle)(TYPE(igraph_vector) *v) {
    igraph_integer_t n = FUNCTION(igraph_vector, size)(v);
    igraph_integer_t k;
    BASE dummy;

    RNG_BEGIN();
    while (n > 1) {
        k = RNG_INTEGER(0, n - 1);
        n--;
        dummy = VECTOR(*v)[n];
        VECTOR(*v)[n] = VECTOR(*v)[k];
        VECTOR(*v)[k] = dummy;
    }
    RNG_END();

    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_add
 * \brief Add two vectors.
 *
 * Add the elements of \p v2 to \p v1, the result is stored in \p
 * v1. The two vectors must have the same length.
 * \param v1 The first vector, the result will be stored here.
 * \param v2 The second vector, its contents will be unchanged.
 * \return Error code.
 *
 * Time complexity: O(n), the number of elements.
 */

igraph_error_t FUNCTION(igraph_vector, add)(TYPE(igraph_vector) *v1,
                                 const TYPE(igraph_vector) *v2) {

    igraph_integer_t n1 = FUNCTION(igraph_vector, size)(v1);
    igraph_integer_t n2 = FUNCTION(igraph_vector, size)(v2);
    igraph_integer_t i;
    if (n1 != n2) {
        IGRAPH_ERROR("Vectors to be added must have the same sizes.",
                     IGRAPH_EINVAL);
    }

    for (i = 0; i < n1; i++) {
#ifdef SUM
        SUM(VECTOR(*v1)[i], VECTOR(*v1)[i], VECTOR(*v2)[i]);
#else
        VECTOR(*v1)[i] += VECTOR(*v2)[i];
#endif
    }

    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_sub
 * \brief Subtract a vector from another one.
 *
 * Subtract the elements of \p v2 from \p v1, the result is stored in
 * \p v1. The two vectors must have the same length.
 * \param v1 The first vector, to subtract from. The result is stored
 *    here.
 * \param v2 The vector to subtract, it will be unchanged.
 * \return Error code.
 *
 * Time complexity: O(n), the length of the vectors.
 */

igraph_error_t FUNCTION(igraph_vector, sub)(TYPE(igraph_vector) *v1,
                                 const TYPE(igraph_vector) *v2) {

    igraph_integer_t n1 = FUNCTION(igraph_vector, size)(v1);
    igraph_integer_t n2 = FUNCTION(igraph_vector, size)(v2);
    igraph_integer_t i;
    if (n1 != n2) {
        IGRAPH_ERROR("Vectors to be subtracted must have the same sizes.",
                     IGRAPH_EINVAL);
    }

    for (i = 0; i < n1; i++) {
#ifdef DIFF
        DIFF(VECTOR(*v1)[i], VECTOR(*v1)[i], VECTOR(*v2)[i]);
#else
        VECTOR(*v1)[i] -= VECTOR(*v2)[i];
#endif
    }

    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_mul
 * \brief Multiply two vectors.
 *
 * \p v1 will be multiplied by \p v2, elementwise. The two vectors
 * must have the same length.
 * \param v1 The first vector, the result will be stored here.
 * \param v2 The second vector, it is left unchanged.
 * \return Error code.
 *
 * Time complexity: O(n), the number of elements.
 */

igraph_error_t FUNCTION(igraph_vector, mul)(TYPE(igraph_vector) *v1,
                                 const TYPE(igraph_vector) *v2) {

    igraph_integer_t n1 = FUNCTION(igraph_vector, size)(v1);
    igraph_integer_t n2 = FUNCTION(igraph_vector, size)(v2);
    igraph_integer_t i;
    if (n1 != n2) {
        IGRAPH_ERROR("Vectors to be multiplied must have the same sizes.",
                     IGRAPH_EINVAL);
    }

    for (i = 0; i < n1; i++) {
#ifdef PROD
        PROD(VECTOR(*v1)[i], VECTOR(*v1)[i], VECTOR(*v2)[i]);
#else
        VECTOR(*v1)[i] *= VECTOR(*v2)[i];
#endif
    }

    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_div
 * \brief Divide a vector by another one.
 *
 * \p v1 is divided by \p v2, elementwise. They must have the same length. If the
 * base type of the vector can generate divide by zero errors then
 * please make sure that \p v2 contains no zero if you want to avoid
 * trouble.
 * \param v1 The dividend. The result is also stored here.
 * \param v2 The divisor, it is left unchanged.
 * \return Error code.
 *
 * Time complexity: O(n), the length of the vectors.
 */

igraph_error_t FUNCTION(igraph_vector, div)(TYPE(igraph_vector) *v1,
                                 const TYPE(igraph_vector) *v2) {

    igraph_integer_t n1 = FUNCTION(igraph_vector, size)(v1);
    igraph_integer_t n2 = FUNCTION(igraph_vector, size)(v2);
    igraph_integer_t i;
    if (n1 != n2) {
        IGRAPH_ERROR("Vectors to be divided must have the same sizes.",
                     IGRAPH_EINVAL);
    }

    for (i = 0; i < n1; i++) {
#ifdef DIV
        DIV(VECTOR(*v1)[i], VECTOR(*v1)[i], VECTOR(*v2)[i]);
#else
        VECTOR(*v1)[i] /= VECTOR(*v2)[i];
#endif
    }

    return IGRAPH_SUCCESS;
}

#ifndef NOABS

igraph_error_t FUNCTION(igraph_vector, abs)(TYPE(igraph_vector) *v) {
#ifdef UNSIGNED
    /* Nothing do to, unsigned type */
    IGRAPH_UNUSED(v);
#else
    igraph_integer_t i, n = FUNCTION(igraph_vector, size)(v);
    for (i = 0; i < n; i++) {
        VECTOR(*v)[i] = VECTOR(*v)[i] >= 0 ? VECTOR(*v)[i] : -VECTOR(*v)[i];
    }
#endif

    return IGRAPH_SUCCESS;
}

#endif

#ifndef NOTORDERED

/**
 * \function igraph_vector_minmax
 * \brief Minimum and maximum elements of a vector.
 *
 * Handy if you want to have both the smallest and largest element of
 * a vector. The vector is only traversed once. The vector must be non-empty.
 * If a vector contains at least one NaN, both \c min and \c max will be NaN.
 *
 * \param v The input vector. It must contain at least one element.
 * \param min Pointer to a base type variable, the minimum is stored here.
 * \param max Pointer to a base type variable, the maximum is stored here.
 *
 * Time complexity: O(n), the number of elements.
 */

void FUNCTION(igraph_vector, minmax)(const TYPE(igraph_vector) *v,
                          BASE *min, BASE *max) {
    BASE* ptr;
    IGRAPH_ASSERT(!FUNCTION(igraph_vector, empty)(v));
    *min = *max = *(v->stor_begin);
    #if defined(BASE_IGRAPH_REAL)
        if (isnan(*min)) { return; }; /* Result is NaN */
    #endif
    ptr = v->stor_begin + 1;
    while (ptr < v->end) {
        if (*ptr > *max) {
            *max = *ptr;
        } else if (*ptr < *min) {
            *min = *ptr;
        }
        #if defined(BASE_IGRAPH_REAL)
        else if (isnan(*ptr)) { /* Result is NaN */
            *min = *max = *ptr;
            return;
        };
        #endif
        ptr++;
    }
}

/**
 * \function igraph_vector_which_minmax
 * \brief Index of the minimum and maximum elements.
 *
 * Handy if you need the indices of the smallest and largest
 * elements. The vector is traversed only once. The vector must be
 * non-empty. If the minimum or maximum is not unique, the index
 * of the first minimum or the first maximum is returned, respectively.
 * If a vector contains at least one NaN, both \c which_min and \c which_max
 * will point to the first NaN value.
 *
 * \param v The input vector. It must contain at least one element.
 * \param which_min The index of the minimum element will be stored
 *   here.
 * \param which_max The index of the maximum element will be stored
 *   here.
 *
 * Time complexity: O(n), the number of elements.
 */

void FUNCTION(igraph_vector, which_minmax)(const TYPE(igraph_vector) *v,
        igraph_integer_t *which_min, igraph_integer_t *which_max) {
    BASE *min, *max;
    BASE *ptr;
    IGRAPH_ASSERT(!FUNCTION(igraph_vector, empty)(v));
    ptr = v->stor_begin;
    min = max = ptr;
    #if defined(BASE_IGRAPH_REAL)
        if (isnan(*ptr)) {  /* Result is NaN */
            *which_min = *which_max = 0;
            return;
        }
    #endif
    while (ptr < v->end) {
        if (*ptr > *max) {
            max = ptr;
        } else if (*ptr < *min) {
            min = ptr;
        }
#if defined(BASE_IGRAPH_REAL)
        else if (isnan(*ptr)) {  /* Result is NaN */
            *which_min = *which_max  = ptr - v->stor_begin;
            return;
        }
#endif
        ptr++;
    }
    *which_min = min - v->stor_begin;
    *which_max = max - v->stor_begin;
}

#endif

/**
 * \function igraph_vector_isnull
 * \brief Are all elements zero?
 *
 * Checks whether all elements of a vector are zero.
 * \param v The input vector
 * \return Boolean, \c true if the vector contains only zeros, \c
 *    false otherwise.
 *
 * Time complexity: O(n), the number of elements.
 */

igraph_bool_t FUNCTION(igraph_vector, isnull)(const TYPE(igraph_vector) *v) {

    igraph_integer_t n = FUNCTION(igraph_vector, size)(v);
    igraph_integer_t i = 0;

#ifdef EQ
    while (i < n && EQ(VECTOR(*v)[i], (BASE) ZERO)) {
#else
    while (i < n && VECTOR(*v)[i] == (BASE) ZERO) {
#endif
        i++;
    }

    return i == n;
}

#ifndef NOTORDERED


/*
 * Sorted vector intersection
 */

/* Recursive Baeza-Yates intersection algorithm for sorted vector intersection. */
static igraph_error_t FUNCTION(igraph_i_vector, intersect_sorted)(
    const TYPE(igraph_vector) *v1, igraph_integer_t begin1, igraph_integer_t end1,
    const TYPE(igraph_vector) *v2, igraph_integer_t begin2, igraph_integer_t end2,
    TYPE(igraph_vector) *result) {
    igraph_integer_t size1, size2, probe1, probe2;

    if (begin1 == end1 || begin2 == end2) {
        return IGRAPH_SUCCESS;
    }

    size1 = end1 - begin1;
    size2 = end2 - begin2;

    if (size1 < size2) {
        probe1 = begin1 + (size1 >> 1);      /* pick the median element */
        FUNCTION(igraph_i_vector, binsearch_slice)(v2, VECTOR(*v1)[probe1], &probe2, begin2, end2);
        IGRAPH_CHECK(FUNCTION(igraph_i_vector, intersect_sorted)(
            v1, begin1, probe1, v2, begin2, probe2, result
        ));
        if (!(probe2 == end2 || VECTOR(*v1)[probe1] < VECTOR(*v2)[probe2])) {
            IGRAPH_CHECK(FUNCTION(igraph_vector, push_back)(result, VECTOR(*v2)[probe2]));
            probe2++;
        }
        IGRAPH_CHECK(FUNCTION(igraph_i_vector, intersect_sorted)(
            v1, probe1 + 1, end1, v2, probe2, end2, result
        ));
    } else {
        probe2 = begin2 + (size2 >> 1);      /* pick the median element */
        FUNCTION(igraph_i_vector, binsearch_slice)(v1, VECTOR(*v2)[probe2], &probe1, begin1, end1);
        IGRAPH_CHECK(FUNCTION(igraph_i_vector, intersect_sorted)(
            v1, begin1, probe1, v2, begin2, probe2, result
        ));
        if (!(probe1 == end1 || VECTOR(*v2)[probe2] < VECTOR(*v1)[probe1])) {
            IGRAPH_CHECK(FUNCTION(igraph_vector, push_back)(result, VECTOR(*v2)[probe2]));
            probe1++;
        }
        IGRAPH_CHECK(FUNCTION(igraph_i_vector, intersect_sorted)(
            v1, probe1, end1, v2, probe2 + 1, end2, result
        ));
    }

    return IGRAPH_SUCCESS;
}

/**
 * \function igraph_vector_intersect_sorted
 * \brief Set intersection of two sorted vectors.
 *
 * The elements that are contained in both vectors are stored in the result
 * vector. All three vectors must be initialized.
 *
 * </para><para>
 * For similar-size vectors, this function uses a straightforward linear scan.
 * When the vector sizes differ substantially, it uses the set intersection
 * method of Ricardo Baeza-Yates, which takes logarithmic time in the length
 * of the larger vector.
 *
 * </para><para>
 * The algorithm keeps the multiplicities of the elements: if an element appears
 * \c k1 times in the first vector and \c k2 times in the second, the result
 * will include that element <code>min(k1, k2)</code> times.
 *
 * </para><para>
 * Reference:
 *
 * </para><para>
 * Baeza-Yates R: A fast set intersection algorithm for sorted
 * sequences. In: Lecture Notes in Computer Science, vol. 3109/2004, pp.
 * 400--408, 2004. Springer Berlin/Heidelberg.
 * https://doi.org/10.1007/978-3-540-27801-6_30
 *
 * \param v1 The first vector
 * \param v2 The second vector
 * \param result The result vector, which will also be sorted.
 * \return Error code.
 *
 * Time complexity: O(m log(n)) where m is the size of the smaller vector
 * and n is the size of the larger one.
 */
igraph_error_t FUNCTION(igraph_vector, intersect_sorted)(const TYPE(igraph_vector) *v1,
        const TYPE(igraph_vector) *v2, TYPE(igraph_vector) *result) {
    igraph_integer_t size1, size2;
    igraph_real_t r;

    size1 = FUNCTION(igraph_vector, size)(v1);
    size2 = FUNCTION(igraph_vector, size)(v2);

    FUNCTION(igraph_vector, clear)(result);

    if (size1 == 0 || size2 == 0) {
        return IGRAPH_SUCCESS;
    }

    r = size1 > size2 ? (igraph_real_t) size1 / size2 : (igraph_real_t) size2 / size1;

    /* When the set size ratio is small, use a simple linear scan. See comments in
     * igraph_vector_intersection_size_sorted() for the justification of this r threshold. */
    if (r < 10) {
        igraph_integer_t i1 = 0, i2 = 0;
        while (i1 < size1 && i2 < size2) {
            BASE e1 = VECTOR(*v1)[i1], e2 = VECTOR(*v2)[i2];
            if (e1 < e2) {
                i1++;
            } else if (e1 > e2) {
                i2++;
            } else {
                i1++; i2++;
                IGRAPH_CHECK(FUNCTION(igraph_vector, push_back)(result, e1));
            }
        }
    } else {
        IGRAPH_CHECK(FUNCTION(igraph_i_vector, intersect_sorted)(
                         v1, 0, size1, v2, 0, size2, result));
    }
    return IGRAPH_SUCCESS;
}

/* Recursive Baeza-Yates intersection algorithm for sorted vector intersection size. */
static void FUNCTION(igraph_i_vector, intersection_size_sorted)(
    const TYPE(igraph_vector) *v1, igraph_integer_t begin1, igraph_integer_t end1,
    const TYPE(igraph_vector) *v2, igraph_integer_t begin2, igraph_integer_t end2,
    igraph_integer_t *result) {

    igraph_integer_t size1, size2, probe1, probe2;

    if (begin1 == end1 || begin2 == end2) {
        return;
    }

    size1 = end1 - begin1;
    size2 = end2 - begin2;

    if (size1 < size2) {
        probe1 = begin1 + (size1 >> 1);      /* pick the median element */
        FUNCTION(igraph_i_vector, binsearch_slice)(v2, VECTOR(*v1)[probe1], &probe2, begin2, end2);
        FUNCTION(igraph_i_vector, intersection_size_sorted)(
            v1, begin1, probe1, v2, begin2, probe2, result
        );
        if (!(probe2 == end2 || VECTOR(*v1)[probe1] < VECTOR(*v2)[probe2])) {
            (*result)++;
            probe2++;
        }
        FUNCTION(igraph_i_vector, intersection_size_sorted)(
            v1, probe1 + 1, end1, v2, probe2, end2, result
        );
    } else {
        probe2 = begin2 + (size2 >> 1);      /* pick the median element */
        FUNCTION(igraph_i_vector, binsearch_slice)(v1, VECTOR(*v2)[probe2], &probe1, begin1, end1);
        FUNCTION(igraph_i_vector, intersection_size_sorted)(
            v1, begin1, probe1, v2, begin2, probe2, result
        );
        if (!(probe1 == end1 || VECTOR(*v2)[probe2] < VECTOR(*v1)[probe1])) {
            (*result)++;
            probe1++;
        }
        FUNCTION(igraph_i_vector, intersection_size_sorted)(
            v1, probe1, end1, v2, probe2 + 1, end2, result
        );
    }
}

/**
 * \function igraph_vector_intersection_size_sorted
 * \brief Intersection size of two sorted vectors.
 *
 * \experimental
 *
 * Counts elements that are present in both vectors. This is particularly
 * useful for counting common neighbours of two vertices.
 *
 * </para><para>
 * For similar-size vectors, this function uses a straightforward linear scan.
 * When the vector sizes differ substantially, it uses the set intersection
 * method of Ricardo Baeza-Yates, which takes logarithmic time in the length
 * of the larger vector.
 *
 * </para><para>
 * The algorithm keeps the multiplicities of the elements: if an element appears
 * \c k1 times in the first vector and \c k2 times in the second, the result
 * will include that element <code>min(k1, k2)</code> times.
 *
 * </para><para>
 * Reference:
 *
 * </para><para>
 * Baeza-Yates R: A fast set intersection algorithm for sorted
 * sequences. In: Lecture Notes in Computer Science, vol. 3109/2004, pp.
 * 400--408, 2004. Springer Berlin/Heidelberg.
 * https://doi.org/10.1007/978-3-540-27801-6_30
 *
 * \param v1 The first vector
 * \param v2 The second vector
 * \return The number of common elements.
 *
 * Time complexity: O(m log(n)) where m is the size of the smaller vector
 * and n is the size of the larger one.
 */

igraph_integer_t FUNCTION(igraph_vector, intersection_size_sorted)(
        const TYPE(igraph_vector) *v1,
        const TYPE(igraph_vector) *v2) {

    igraph_integer_t size1, size2, count;
    igraph_real_t r;

    size1 = FUNCTION(igraph_vector, size)(v1);
    size2 = FUNCTION(igraph_vector, size)(v2);

    count = 0;

    if (size1 == 0 || size2 == 0) {
        return count;
    }

    r = size1 > size2 ? (igraph_real_t) size1 / size2 : (igraph_real_t) size2 / size1;

    /* When the set size ratio is small, use a simple linear scan. The ideal ratio
     * seems to be affected by processor cache effects. It depends on the machine,
     * as well as on the input sizes. The threshold of 10 was determined empirically
     * by using the intersection.c (direct) and igraph_ecc.c (indirect) benchmarks.
     * See https://github.com/igraph/igraph/pull/2618 */
    if (r < 10) {
        /* This is a fast branchless implementation that uses arithmetic
         * instead of conditionals. */
        igraph_integer_t i1 = 0, i2 = 0;
        while (i1 < size1 && i2 < size2) {
            BASE e1 = VECTOR(*v1)[i1], e2 = VECTOR(*v2)[i2];
            igraph_integer_t d1 = (e1 <= e2), d2 = (e1 >= e2);
            i1 += d1; i2 += d2;
            count += (d1 == d2);
        }
    } else {
        FUNCTION(igraph_i_vector, intersection_size_sorted)(
            v1, 0, size1, v2, 0, size2, &count);
    }

    return count;
}

/**
 * \function igraph_vector_difference_sorted
 * \brief Set difference of two sorted vectors.
 *
 * The elements that are contained in only the first vector but not the second are
 * stored in the result vector. All three vectors must be initialized.
 *
 * \param v1 the first vector
 * \param v2 the second vector
 * \param result the result vector
 */
igraph_error_t FUNCTION(igraph_vector, difference_sorted)(const TYPE(igraph_vector) *v1,
        const TYPE(igraph_vector) *v2, TYPE(igraph_vector) *result) {
    igraph_integer_t i, j, i0, j0;
    i0 = FUNCTION(igraph_vector, size)(v1);
    j0 = FUNCTION(igraph_vector, size)(v2);
    i = j = 0;

    if (i0 == 0) {
        /* v1 is empty, this is easy */
        FUNCTION(igraph_vector, clear)(result);
        return IGRAPH_SUCCESS;
    }

    if (j0 == 0) {
        /* v2 is empty, this is easy */
        IGRAPH_CHECK(FUNCTION(igraph_vector, resize)(result, i0));
        memcpy(result->stor_begin, v1->stor_begin, sizeof(BASE) * i0);
        return IGRAPH_SUCCESS;
    }

    FUNCTION(igraph_vector, clear)(result);

    /* Copy the part of v1 that is less than the first element of v2 */
    while (i < i0 && VECTOR(*v1)[i] < VECTOR(*v2)[j]) {
        i++;
    }
    if (i > 0) {
        IGRAPH_CHECK(FUNCTION(igraph_vector, resize)(result, i));
        memcpy(result->stor_begin, v1->stor_begin, sizeof(BASE) * i);
    }

    while (i < i0 && j < j0) {
        BASE element = VECTOR(*v1)[i];
        if (element == VECTOR(*v2)[j]) {
            i++; j++;
            while (i < i0 && VECTOR(*v1)[i] == element) {
                i++;
            }
            while (j < j0 && VECTOR(*v2)[j] == element) {
                j++;
            }
        } else if (element < VECTOR(*v2)[j]) {
            IGRAPH_CHECK(FUNCTION(igraph_vector, push_back)(result, element));
            i++;
        } else {
            j++;
        }
    }
    if (i < i0) {
        igraph_integer_t oldsize = FUNCTION(igraph_vector, size)(result);
        IGRAPH_CHECK(FUNCTION(igraph_vector, resize)(result, oldsize + i0 - i));
        memcpy(result->stor_begin + oldsize, v1->stor_begin + i,
               sizeof(BASE) * (i0 - i));
    }

    return IGRAPH_SUCCESS;
}

#endif

#ifdef OUT_FORMAT
#ifndef USING_R
igraph_error_t FUNCTION(igraph_vector, printf)(const TYPE(igraph_vector) *v, const char *format) {
    igraph_integer_t i, n = FUNCTION(igraph_vector, size)(v);
    if (n != 0) {
        printf(format, VECTOR(*v)[0]);
    }
    for (i = 1; i < n; i++) {
        putchar(' '); printf(format, VECTOR(*v)[i]);
    }
    printf("\n");
    return IGRAPH_SUCCESS;
}
#endif /* USING_R */
#endif /* OUT_FORMAT */

#if defined(OUT_FORMAT) || defined(FPRINTFUNC)

#ifndef USING_R
igraph_error_t FUNCTION(igraph_vector, print)(const TYPE(igraph_vector) *v) {
    return FUNCTION(igraph_vector, fprint)(v, stdout);
}
#endif

igraph_error_t FUNCTION(igraph_vector, fprint)(const TYPE(igraph_vector) *v, FILE *file) {
    igraph_integer_t i, n = FUNCTION(igraph_vector, size)(v);
    if (n != 0) {
#ifdef FPRINTFUNC
        FPRINTFUNC(file, VECTOR(*v)[0]);
#else
        fprintf(file, OUT_FORMAT, VECTOR(*v)[0]);
#endif
    }
    for (i = 1; i < n; i++) {
#ifdef FPRINTFUNC
        fputc(' ', file); FPRINTFUNC(file, VECTOR(*v)[i]);
#else
        fprintf(file, " " OUT_FORMAT, VECTOR(*v)[i]);
#endif
    }
    fprintf(file, "\n");
    return IGRAPH_SUCCESS;
}

#endif /* defined(OUT_FORMAT) || defined(FPRINTFUNC) */

igraph_error_t FUNCTION(igraph_vector, index)(const TYPE(igraph_vector) *v,
                                   TYPE(igraph_vector) *newv,
                                   const igraph_vector_int_t *idx) {

    igraph_integer_t i, j, newlen = igraph_vector_int_size(idx);
    IGRAPH_CHECK(FUNCTION(igraph_vector, resize)(newv, newlen));

    for (i = 0; i < newlen; i++) {
        j = VECTOR(*idx)[i];
        VECTOR(*newv)[i] = VECTOR(*v)[j];
    }

    return IGRAPH_SUCCESS;
}

igraph_error_t FUNCTION(igraph_vector, index_int)(TYPE(igraph_vector) *v,
                                       const igraph_vector_int_t *idx) {
    BASE *tmp;
    igraph_integer_t i, n = igraph_vector_int_size(idx);

    tmp = IGRAPH_CALLOC(n, BASE);
    if (!tmp) {
        IGRAPH_ERROR("Cannot index vector.", IGRAPH_ENOMEM); /* LCOV_EXCL_LINE */
    }

    for (i = 0; i < n; i++) {
        tmp[i] = VECTOR(*v)[ VECTOR(*idx)[i] ];
    }

    IGRAPH_FREE(v->stor_begin);
    v->stor_begin = tmp;
    v->stor_end = v->end = tmp + n;

    return IGRAPH_SUCCESS;
}
